JP2020116347A - Game machine - Google Patents

Abstract

To provide a game machine capable of suitably executing processing regarding a setting value for determining a degree of advantage of a player.SOLUTION: When operating power starts to be supplied, processing for changing a setting value is executable. Setting processing as partial processing of processing for changing a setting value is executed by main processing started when operating power starts to be supplied, and setting correspondence processing as another partial processing is executed by first timer interruption processing started periodically. More specifically, not only setting for progressing a game but also setting for changing a setting value are set to the first timer interruption processing. When processing for changing a setting value is started, a power on command and a setting change command are transmitted to a sound and light-emission controller 81. Even if a situation in which processing for changing a setting value is under execution, putout state reception processing is executed.SELECTED DRAWING: Figure 6

Description

The present invention relates to a gaming machine.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper side dish storage section are discharged to the lower side dish storage section (for example, refer to Patent Document 1).

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

JP, 2013-106772, A

Here, in the gaming machine as illustrated above, it is necessary to suitably execute the processing relating to the set value that determines the degree of advantage of the player, and there is still room for improvement in this respect.

The present invention has been made in view of the above-exemplified circumstances, and an object thereof is to provide a gaming machine capable of suitably executing a process relating to a set value that determines the advantage of a player. Is.

In order to solve the above problems, the invention according to claim 1 is a progress control means for controlling the progress of a game,
A notification control means for performing notification based on the instruction information transmitted from the progress control means,
Equipped with
The progress control means,
A profit giving process executing means for executing a profit giving process in a mode corresponding to a setting value set as a usage target from a plurality of setting values corresponding to a player's advantage,
Setting-related executing means for executing a predetermined setting-related process relating to the set value based on the start of supply of operating power,
First transmitting means for transmitting a first type of instruction information when the setting related processing is executed;
Second transmitting means for transmitting second type instruction information when the setting-related processing is executed;
Equipped with
The notification control means,
Reception specifying means for specifying whether or not the first type of instruction information has been received within a predetermined period from the start of supply of operating power,
A non-reception-corresponding notification execution means for executing non-reception-corresponding notification when the first type instruction information is not received within the predetermined period;
Second reception-corresponding notification executing means for executing notification corresponding to the second type of instruction information received,
It is characterized by having.

According to the present invention, it is possible to preferably execute the processing relating to the set value that determines the degree of advantage of the player.

It is a perspective view showing a pachinko machine in the first embodiment. It is a perspective view which decomposes|disassembles and shows the main structures of a pachinko machine. It is a front view showing a configuration of a game board. It is explanatory drawing for demonstrating the structure regarding the discharge of the game ball which flowed down the game area. It is a front view of a main controller. It is a block diagram which shows the electric constitution of a pachinko machine. It is an explanatory view for explaining the contents of various counters used for win/win lottery. It is an explanatory view for explaining various tables memorized by main side ROM. It is a flow chart which shows the main processing performed by the master side CPU. It is a flow chart which shows the setting value update processing performed by the main CPU. It is a flowchart which shows the timer interruption process performed by the main side CPU. It is a flow chart which shows the special figure special electric power control processing performed by the main side CPU. It is a flowchart which shows the special figure fluctuation|variation start process performed by the main side CPU. It is explanatory drawing for demonstrating the structure which makes the detection result of a ball detection sensor input into a main side CPU. It is a flow chart which shows the entrance detection processing performed by the main side CPU. It is a block diagram for explaining an electric configuration of a payout control device and various devices that communicate with the payout control device. It is a flow chart which shows timer interruption processing performed by a payment side CPU. It is a block diagram for explaining an electric configuration of a management IC. It is an explanatory view for explaining the composition of the input port of the management side I/F. It is an explanatory view for explaining the composition of a correspondence memory. It is an explanatory view for explaining the composition of a history memory. It is a flowchart which shows the process for recognition performed by the main side CPU. It is a flow chart which shows the management processing performed by the management side CPU. (A) ~ (d) is a time chart showing a state in which information on the correspondence between the first to fifteenth buffers and the types of signals is stored in the correspondence memory. It is a flow chart which shows management output processing performed by the master side CPU. It is a flow chart which shows history setting processing performed by a management side CPU. 8A to 8E are time charts showing how history information is stored in the history memory. It is a flowchart which shows the output processing of the setting value update signal performed by the main side CPU. 7 is a flowchart showing a setting update recognition process executed by a management CPU. It is a flow chart which shows display output processing performed by a management side CPU. 8 is a flowchart showing a display process executed by the management-side CPU. (A) It is a flowchart which shows the data output process performed by the main side CPU, and (b) is a flowchart which shows the external output process performed by the management side CPU. It is an explanatory view for explaining various tables memorized by main side ROM in a 2nd embodiment. It is explanatory drawing for demonstrating the structure of the memory for another preservation|save in 3rd Embodiment. 7 is a flowchart showing a setting update recognition process executed by a management CPU. 7 is a flowchart showing a monitoring process for repeated changes executed by the management CPU. It is a flowchart which shows the monitoring process of the repeated change performed by the main side CPU in 4th Embodiment. It is a flowchart which shows the process for a setting update recognition performed by the management side CPU in 5th Embodiment. It is explanatory drawing for demonstrating the structure of the memory for history records in 6th Embodiment. It is a flow chart which shows history setting processing performed by a management side CPU. 7 is a flowchart showing a setting update recognition process executed by a management CPU. It is explanatory drawing for demonstrating the structure of the memory for history in 7th Embodiment. 7 is a flowchart showing a setting update recognition process executed by a management CPU. It is explanatory drawing for demonstrating the structure of the memory for history records in 8th Embodiment. 7 is a flowchart showing a setting update recognition process executed by a management CPU. It is a flow chart which shows history setting processing performed by a management side CPU. It is a flow chart which shows display output processing performed by a management side CPU. It is explanatory drawing for demonstrating the structure of the input port of the management side I/F in 9th Embodiment. It is a flowchart which shows the process for recognition performed by the main side CPU. It is a flow chart which shows the management processing performed by the management side CPU. (A) ~ (h) is a time chart showing a state in which information on the correspondence between the first to twelfth buffers and the types of signals is stored in the correspondence memory. It is a block diagram for demonstrating the structure of the signal path which transmits the detection result of each ball detection sensor in 10th Embodiment to the main side CPU and management IC. It is a front view of the main control unit in an 11th embodiment. It is a block diagram for demonstrating the electrical structure for performing various displays in the 1st-4th notification display apparatus based on control of MPU. 8 is a flowchart showing a display process executed by the management-side CPU. It is a flow chart which shows the setting value update processing performed by the main CPU. (A) It is explanatory drawing for demonstrating the display mode of the 1st-4th notification display apparatus in case the management result of a game history is displayed, (b) in the case where the setting state of a pachinko machine is changed It is explanatory drawing for demonstrating the display mode of the 1st-4th notification display apparatus. It is a time chart which shows a mode that (a)-(h) 1st-4th notification display apparatus will be in a display state. (A) It is explanatory drawing for demonstrating the structure of the 1st notification display apparatus in 12th Embodiment, (b) It is explanatory drawing for demonstrating the structure of the 2nd notification display apparatus. A first notification display device in the case of displaying a game history management result on the first to fourth notification displays and in a case of displaying a changeable state in which the setting state of a pachinko machine can be changed 6A and 6B are explanatory diagrams for explaining display contents of the second notification display device. It is a flow chart which shows the setting value update processing performed by the main CPU. It is explanatory drawing for demonstrating the structure of the abnormality display area in 13th Embodiment. It is a flowchart which shows the abnormality setting process performed by the main side CPU. It is a flowchart which shows the abnormality display process performed by the main CPU. It is a flow chart which shows management output processing performed by the main side CPU in a 14th embodiment. It is a flowchart which shows the main process performed by the main side CPU in another form. It is explanatory drawing for demonstrating the setting aspect of the program and data of the main side ROM in 15th Embodiment. It is an explanatory view for explaining a setting mode of each area in the main side RAM. It is a flowchart which shows the timer interruption process performed by the main side CPU. It is a flow chart which shows management processing performed by a master side CPU. It is a flow chart which shows management execution processing performed by a master side CPU. It is an explanatory view for explaining various areas of a work area for non-specific control used for managing a game history. It is a flowchart which shows the check process performed by the main side CPU. It is a flow chart which shows the usual entrance management processing performed by the master side CPU. It is a flowchart which shows the result calculation process performed by the main side CPU. 6 is a flowchart showing a display process executed by a main CPU. It is a flow chart which shows management processing performed by the main side CPU in a 16th embodiment. It is a flowchart which shows the management execution process performed by the main side CPU in a 17th embodiment. It is a flowchart which shows the management execution process performed by the main side CPU in 18th Embodiment. It is a flowchart which shows the management execution process performed by the main side CPU in 19th Embodiment. It is a flowchart which shows the management process performed by the main side CPU in 20th Embodiment. It is a flow chart which shows management execution processing performed by a master side CPU. It is an explanatory view for explaining the electric composition in a 21st embodiment. It is a flow chart which shows the main processing performed by the main side CPU in a 22nd embodiment. It is a flow chart which shows the setting value update processing performed by the main CPU. It is a flowchart which shows the timer interruption process performed by the main side CPU. 8 is a flowchart showing a setting confirmation process executed by the main CPU. 7 is a flowchart showing a RAM monitoring process executed by the main CPU. It is a flowchart which shows the main process performed by the main side CPU in another form. It is a flowchart which shows the setting value update process performed by the main side CPU in another form. It is a flow chart which shows the main processing performed by the main side CPU in a 23rd embodiment. It is a flowchart which shows the RAM monitoring process performed by the main CPU in 24th Embodiment. It is a flowchart which shows the RAM monitoring process performed by the main CPU in 25th Embodiment. It is a flow chart which shows management execution processing performed by a master side CPU. It is a flowchart which shows another monitoring process performed by the main side CPU. It is a flowchart which shows the management process performed by the main CPU in 26th Embodiment. It is a flowchart which shows the process for management performed by the main side CPU in 27th Embodiment. It is a flowchart which shows the process for management performed by the main CPU in 28th Embodiment. It is a flowchart which shows the management process performed by the main CPU in 29th Embodiment. It is a flow chart which shows the main processing performed by the main side CPU in a 30th embodiment. It is a flow chart which shows blackout information storage processing performed by the main side CPU. (A) is a block diagram for explaining the configuration of the MPU, and (b) is a time chart showing how the reset signal output section outputs the reset signal. It is a flowchart which shows the timer interruption process performed by the main side CPU. 6 is a flowchart showing a setting monitoring process executed by a main CPU. It is a flow chart which shows management processing performed by a master side CPU. It is a flow chart which shows management execution processing performed by a master side CPU. It is a flowchart which shows another monitoring process performed by the main side CPU. It is a flow chart which shows the main processing performed by the main side CPU in a 31st embodiment. It is a flow chart which shows clear processing at the time of abnormalities which is performed by a master side CPU. It is a flowchart which shows the clear process for non-specific control performed by the main side CPU. It is a flow chart which shows blackout information storage processing performed by a main side CPU in a 32nd embodiment. 7 is a flowchart showing checksum monitoring processing executed by the main CPU. It is a flowchart which shows the clear process for non-specific control performed by the main side CPU. It is a flow chart which shows the main processing performed by the main side CPU in a 33rd embodiment. 8 is a flowchart showing a setting confirmation process executed by the main CPU. It is a flow chart which shows the setting value update processing performed by the main CPU. It is a flow chart which shows the 1st timer interruption processing performed by the main side CPU. 6 is a flowchart showing a setting monitoring process executed by a main CPU. It is a block diagram for explaining a configuration for controlling display of various display circuits by the main CPU. (A) It is an explanatory view for explaining various buffers provided in a work area for specific control, and (b) is an explanatory view for explaining various storage areas provided in a work area for non-specific control. is there. It is an explanatory view for explaining the electric composition of a display IC. (A) to (g) shows how the main CPU transmits the type data and the display data to the display IC and the display data transmitted from the display IC is received by the first display circuit or the second display circuit. It is a time chart. It is a flow chart which shows the 2nd timer interruption processing performed by the main side CPU. (A) It is explanatory drawing for demonstrating the display content of the 1st-4th notification display apparatus in the situation where a setting value is updated, (b) The 1st-4th notification in the situation where a setting value is confirmed. FIG. 7 is an explanatory diagram for explaining display contents of the display device for display. It is a flowchart which shows the setting value update process performed by the main side CPU in 34th Embodiment. It is explanatory drawing for demonstrating the electric constitution of the calculation result storage area in 35th Embodiment. (A)-(d) It is explanatory drawing for demonstrating the display content of the 1st-4th notification display apparatus. (A)-(c) It is explanatory drawing for demonstrating the display content of the 1st-4th notification display apparatus. (A) ~ (e) is a time chart showing how the base values of various areas are notified on the first to fourth notification display devices. It is a flowchart which shows the result calculation process performed by the main side CPU. 6 is a flowchart showing a display process executed by a main CPU. It is a flow chart which shows the main processing performed by the master side CPU. It is a flow chart which shows the 1st timer interruption processing performed by the main side CPU. It is a flow chart which shows the 2nd timer interruption processing performed by the main side CPU. It is a flow chart which shows the setting processing at the time of normal performed by the side CPU. 8 is a flowchart showing a setting confirmation process executed by the main CPU. It is a flow chart which shows the setting value update processing performed by the main CPU. (A) ~ (f) is a time chart for explaining the display contents of the first to fourth notification display device when the supply of operating power to the main CPU is started. It is a flow chart which shows the main processing performed by the main side CPU in a 36th embodiment. It is a flow chart which shows the main processing performed by the main side CPU in a 37th embodiment. It is a flowchart which shows the setting process at the time of normal performed by the main CPU in 38th Embodiment. (A)-(d) It is explanatory drawing for demonstrating the setting corresponding|compatible storage area provided in the main side ROM in 39th Embodiment. It is a flowchart which shows the read-out process of the winning/losing table performed by the main side CPU. It is a flowchart which shows the setting process to the 5th display data buffer during setting update performed by the main side CPU. (A)-(c) It is explanatory drawing for demonstrating the setting corresponding storage area provided in the main side ROM in 40th Embodiment. (A) It is explanatory drawing for demonstrating the various display parts provided in the area|region visible from the front of a pachinko machine through the window panel in 41st Embodiment, (b) The display content of a round display part is demonstrated. FIG. It is a flow chart which shows the main processing performed by the main side CPU in a 42nd embodiment. It is a flow chart which shows the 1st timer interruption processing performed by the main side CPU. It is a flowchart which shows the result calculation process performed by the main side CPU in 43rd Embodiment. 6 is a flowchart showing a display process executed by a main CPU. (A) ~ (g) is a time chart showing how the base values of various areas are notified on the first to fourth notification display devices. (A)-(g) It is a time chart which shows a mode that the base value of various areas is notified by the 1st-4th indicator display in a 44th embodiment. It is a flow chart which shows the main processing performed by the main side CPU in a 45th embodiment. It is an explanatory view for explaining the contents of a storage area related to set values provided in a work area for specific control. 8 is a flowchart showing a setting confirmation process executed by the main CPU. It is a flowchart which shows the setting process to the 5th display data buffer during setting confirmation performed by the main side CPU. It is a flow chart which shows the setting value update processing performed by the main CPU. It is a flowchart which shows the setting process to the 5th display data buffer during setting update performed by the main side CPU. Description for explaining the content of the processing executed in the main processing when the supply of operating power is resumed after the power outage processing is executed in the situation where the setting value update processing or the setting confirmation processing is executed It is a figure. 8A to 8E are time charts showing the end timings in relation to the operation state of the setting key insertion portion of the setting value update processing and the setting confirmation processing. It is a flow chart which shows the main processing performed by the main side CPU in a 46th embodiment. Description for explaining the content of the processing executed in the main processing when the supply of operating power is resumed after the power outage processing is executed in the situation where the setting value update processing or the setting confirmation processing is executed It is a figure. Details of the processing executed in the main processing when the supply of operating power is resumed after the power failure processing is executed in the situation where the setting value update processing or the setting confirmation processing is executed in the forty-seventh embodiment It is an explanatory view for explaining. Details of the processing executed in the main processing when the supply of operating power is resumed after the power failure processing is executed in the situation where the setting value update processing or the setting confirmation processing is executed in the forty-eighth embodiment It is an explanatory view for explaining. It is a flow chart which shows the main processing performed by the main side CPU in a 49th embodiment. 8 is a flowchart showing a setting confirmation process executed by the main CPU. It is a flow chart which shows the setting value update processing performed by the main CPU. (A) ~ (h) is a time chart showing how the interrupts of the first timer interrupt process and the second timer interrupt process are permitted in the situation where the process at the start of supplying the operating power is being executed. (A) ~ (g) is a time chart showing the progress of the process when an abnormality related to the power failure flag, the checksum or the set value occurs. (A) ~ (g) is a time chart showing the display contents of the first to fourth notification display devices when the supply of operating power to the main CPU is started. Description for explaining the content of the processing executed in the main processing when the supply of operating power is resumed after the power outage processing is executed in the situation where the setting value update processing or the setting confirmation processing is executed It is a figure. It is explanatory drawing for demonstrating the electric constitution of a sound emission control device. It is the flowchart which shows the production control processing which is executed with the sound side CPU. It is an explanatory view for explaining an operation corresponding to the contents of the processing executed in the processing at the time of starting the supply of the operating power in the main CPU. It is a flow chart which shows the production control processing performed by the sound light side CPU in a 50th embodiment. It is an explanatory view for explaining an operation corresponding to the contents of the processing executed in the processing at the time of starting the supply of the operating power in the main CPU. It is a flow chart which shows the main processing performed by the main side CPU in a 51st embodiment. It is a flow chart which shows the main processing performed by the main side CPU in a 52nd embodiment. It is a flow chart which shows the main processing performed by the main side CPU in a 53rd embodiment. (A) ~ (g) is a time chart showing the state of the subsequent processing when the supply of operating power to the main CPU is stopped in the situation where the set value updating processing is being executed. It is a flow chart which shows the setting value update processing performed by the main CPU. It is an explanatory view for explaining the contents of a storage area provided in a work area for specific control. It is a time chart which shows a mode that the setting value of (a)-(f) update object is updated. It is a flow chart which shows the main processing performed by the main side CPU in a 54th embodiment. It is a flow chart which shows the main processing performed by the main side CPU in a 55th embodiment. It is an explanatory view for explaining a clear target area and a clear target non-clear area provided in a work area for specific control. It is a flowchart which shows the display start process performed by the main side CPU. It is a flow chart which shows the 2nd timer interruption processing performed by the main side CPU. It is explanatory drawing for demonstrating the display content of the special figure display part and general figure display part corresponding to the situation at the time of the supply of operating electric power. It is explanatory drawing for demonstrating each area provided in the clear target area of the work area for specific controls in 56th Embodiment. It is a flowchart which shows the display start process performed by the main side CPU. It is explanatory drawing for demonstrating the display content of the special figure display part and general figure display part corresponding to the situation at the time of the supply of operating electric power. It is a flowchart which shows the display start process performed by the main side CPU in 57th Embodiment. It is explanatory drawing for demonstrating the display content of the special figure display part and general figure display part corresponding to the situation at the time of the supply of operating electric power. It is explanatory drawing for demonstrating each area provided in the clear target area and the non-clear target area of the work area for specific controls in 58th Embodiment. It is a flow chart which shows the 1st timer interruption processing performed by the main side CPU. It is a flowchart which shows the display start process performed by the main side CPU. (A) It is explanatory drawing for demonstrating the deviation display lottery table for special figures, (b) It is explanatory drawing for demonstrating the deviation display lottery table for general figures. It is a flowchart which shows the display start process performed by the main side CPU in 59th Embodiment. (A) It is explanatory drawing for demonstrating the initial display lottery table for special figures, (b) It is explanatory drawing for demonstrating the initial display lottery table for general drawings. It is explanatory drawing for demonstrating the display content of the special figure display part and general figure display part corresponding to the situation at the time of the supply of operating electric power. It is a flow chart which shows the display start processing performed by the main side CPU in a 60th embodiment. It is explanatory drawing for demonstrating the display content of the special figure display part and general figure display part corresponding to the situation at the time of the supply of operating electric power. It is a flowchart which shows the display start process performed by the main side CPU in 61st Embodiment. It is a flowchart which shows the setting value update process performed by the main side CPU in 62nd Embodiment. It is a flowchart which shows the display start process performed by the main side CPU. (A) It is explanatory drawing for demonstrating the 1st display allocation table for special figures, (b) It is explanatory drawing for demonstrating the 2nd display allocation table for special drawings, (c) It is an explanatory view. It is explanatory drawing for demonstrating the 1st display allocation table for drawings, and (d) It is explanatory drawing for demonstrating the 2nd display allocation table for general drawings. It is a flowchart which shows the display start process performed by the main side CPU in 63rd Embodiment. It is a front view of a game board in a 64th embodiment. (A) It is a longitudinal cross-sectional view of the 2nd operation part in the case of a non-induction state, and (b) It is a longitudinal cross-sectional view of the 2nd operation part in the case of an induction state. (A), (b) It is an explanatory view for explaining the display contents of the symbol display device when the game times are executed. (A) ~ (j) is an explanatory view for explaining the main symbol and the sub symbol that are variably displayed in each symbol row. It is a longitudinal cross-sectional view for explaining the internal configuration of the distribution winning apparatus. It is explanatory drawing for demonstrating the electric constitution for performing various lottery in main side CPU. (A) It is explanatory drawing for demonstrating the hit/damage table of a 1st special figure, (b) It is explanatory drawing for demonstrating the hit/miss table of a 2nd special drawing. (A) It is explanatory drawing for demonstrating the classification table for big hits, (b) It is explanatory drawing for demonstrating each content of several kinds of big hit results, (c) The classification table for small hits It is explanatory drawing for demonstrating, (d) It is explanatory drawing for demonstrating each content of several types of small hit results. It is a flowchart which shows the universal figure universal communication control process performed by the main side CPU. It is a flow chart which shows the special figure special electric power control processing performed by the main side CPU. It is a flowchart which shows the special figure fluctuation|variation start process performed by the main side CPU. It is a flow chart which shows the special figure finalization processing performed by the master side CPU. It is a flow chart which shows distribution processing performed by a master side CPU. It is a flow chart which shows special electric power end processing performed by a master side CPU. It is an explanatory view for explaining each area provided in a clear target area of a work area for specific control. It is a flow chart which shows the 2nd timer interruption processing performed by the main side CPU. (A) It is a flowchart which shows the setting process to the 1st display data buffer during setting update performed by the main side CPU, (b) The 6th display data buffer during setting confirmation performed by the main side CPU. 5 is a flowchart showing a setting process for setting to. (A) ~ (g) is a time chart showing how the display contents of the first special figure display section, the second special figure display section and the special display section change according to the state of the pachinko machine. It is a flow chart which shows the 2nd timer interruption processing performed by the main side CPU in a 65th embodiment. It is a flow chart which shows the 2nd timer interruption processing performed by the main side CPU in a 66th embodiment. It is a flow chart which shows the setting value update processing performed by the main CPU. It is a flow chart which shows the 2nd timer interruption processing performed by the main side CPU in a 67th embodiment. (A) It is explanatory drawing for demonstrating the structure of the special display part in 68th Embodiment, (b) 15R display part and 6R display part in the situation where the setting value update process or the process for setting confirmation is performed. 9 is a time chart showing the display contents of the small hitting display unit. It is a front view of the game board in the 69th embodiment. It is explanatory drawing for demonstrating the electric constitution for performing various lottery in main side CPU. (A) It is explanatory drawing for demonstrating the 1st hit/miss table at the time of low probability, (b) It is explanatory drawing for demonstrating the 1st hit/miss table at the time of high probability, (c) It is an explanatory view at the time of low probability. It is explanatory drawing for demonstrating a 2 win/loss table, and (d) is an explanatory view for demonstrating the 2nd win/loss table at the time of high probability. (A) It is explanatory drawing for demonstrating a classification table, (b) It is explanatory drawing for demonstrating the content of each of several types of big hit results, and the content of one kind of small hit result, (c) Support It is explanatory drawing for demonstrating the content of the mode. It is explanatory drawing for demonstrating the setting aspect of the display continuation period of a game time. It is a flow chart which shows the 1st special figure special power control processing performed by the main side CPU. It is a flow chart which shows the 2nd special figure special power control processing performed by the main side CPU. It is a flowchart which shows the special figure fluctuation|variation start process performed by the main side CPU. It is a flow chart which shows the special figure finalization processing performed by the master side CPU. (A) It is explanatory drawing for demonstrating the 1st hit/miss table at the time of low probability in 70th Embodiment, (b) It is explanatory drawing for demonstrating the 1st hit/miss table at the time of high probability, (c) ) It is explanatory drawing for demonstrating the 2nd hit/miss table at the time of low probability, (d) It is explanatory drawing for demonstrating the 2nd hit/miss table at the time of high probability. (A) It is explanatory drawing for demonstrating the 1st hit/miss table at the time of low probability in 71st Embodiment, (b) It is explanatory drawing for demonstrating the 1st hit/miss table at the time of high probability, (c) ) It is explanatory drawing for demonstrating the 2nd hit/miss table at the time of low probability, (d) It is explanatory drawing for demonstrating the 2nd hit/miss table at the time of high probability. It is a front view of the game board in the 72nd embodiment. It is explanatory drawing for demonstrating the electric constitution of a main control apparatus and a sound emission control apparatus. It is a flow chart which shows the main processing performed by the master side CPU. 8 is a flowchart showing a setting confirmation process executed by the main CPU. It is a flow chart which shows the setting value update processing performed by the main CPU. It is an explanatory view for explaining a setting mode of each area in the main side RAM. (A) It is an explanatory view for explaining the contents of the address counter, and (b)-(e) is an explanatory view for explaining how the carry flag is set to "1" as a result of updating the target address. Is. 8 is a flowchart showing a RAM clearing process executed by the main CPU. It is a flowchart which shows the addition process of the target address performed by the main side CPU. It is a flowchart which shows the clear process for non-specific control performed by the main side CPU. 7 is a flowchart showing a checksum calculation process executed by the main CPU. It is the flowchart which shows the production control processing which is executed with the sound side CPU. (A) to (f) When the supply of operating power to the main CPU and the sound/light side CPU is started, the check display is executed on the first to fourth notification display devices and the movable body is used. 7 is a time chart showing how the initial operation is executed. It is a flow chart which shows the production control processing performed by the sound light side CPU in a 73rd embodiment. It is a flow chart which shows the main processing performed by the main side CPU in a 74th embodiment. 8 is a flowchart showing a setting confirmation process executed by the main CPU. It is a flow chart which shows the setting value update processing performed by the main CPU. 8 is a flowchart showing a RAM clearing process executed by the main CPU. It is a flowchart which shows the opening/closing monitoring process performed by the main CPU. It is explanatory drawing for demonstrating the electric constitution of a sound emission control device. It is explanatory drawing for demonstrating the content of the notification table after confirmation. It is explanatory drawing for demonstrating the relationship between the table for various notifications, and the kind of execution area used as a read target. (A) ~ (h) is a time chart showing the relationship between the post-confirmation notification and the main body closure notification, and the relationship between the post-clearing notification and the main body closure notification. It is the flowchart which shows the production control processing which is executed with the sound side CPU. It is a flow chart which shows the task processing performed by the sound side CPU. It is a flow chart which shows the 1st timer interruption processing performed by the main side CPU in a 75th embodiment. It is a flowchart which shows the check process performed by the main side CPU. It is a flowchart which shows the result calculation process performed by the main side CPU. It is a flow chart which shows the special figure special electric power control processing performed by the main side CPU. It is a flow chart which shows processing during special electric power release performed by the main side CPU. 7 is a flowchart showing an ending process executed by the main CPU. It is explanatory drawing for demonstrating an example of the ending production performed with (a), (b) symbol display device. It is an explanatory view for explaining the data structure of the main side ROM. It is explanatory drawing for demonstrating the selection probability of the 1st-5th suggestion production information when each of various tables is selected. It is a flow chart which shows ending production control processing performed by a voice luminescence control device. It is a flowchart which shows the process for endings performed by the main side CPU in 76th Embodiment. It is a flow chart which shows the 1st timer interruption processing performed by the main side CPU in a 77th embodiment. (A) It is explanatory drawing for demonstrating the sensor for monitoring fraud, (b) It is a flowchart which shows the fraud detection process performed by the main side CPU. It is a flow chart which shows the 2nd timer interruption processing performed by the main side CPU. It is an explanatory view for explaining a storage area in a sound-light side RAM. It is a flow chart which shows a sound-light side starting processing performed by a sound-light side CPU. It is a flowchart which shows the sound side timer interrupt process performed by the sound side CPU. It is the flowchart which shows the processing for start waiting production which is executed by the sound side CPU. (A) ~ (i) is a time chart showing how the demonstration effect is executed after the supply of operating power to the pachinko machine is started. (A) ~ (e) is a time chart showing how the demonstration effect is started after a period in which neither the effect for the opening/closing execution mode nor the effect for game play has been executed becomes a preset period. .. It is a flowchart which shows the sound-light side start-up process performed by the sound-light side CPU in 78th Embodiment. It is the flowchart which shows the processing for start waiting production which is executed by the sound side CPU. (A) It is explanatory drawing for demonstrating the memory area provided in the work area for specific control in 79th Embodiment, (b) The initialization non-initialization area and initialization initialization area in sound-light side RAM are shown. It is an explanatory view for explaining. It is a flow chart which shows a sound-light side starting processing performed by a sound-light side CPU. It is a flowchart which shows the timing change lottery process performed by (a) CPU on the sound-light side, and (b) an explanatory view for explaining the timing change lottery table. (A) It is a flowchart which shows the timing change lottery process performed by the sound-light side CPU in 80th Embodiment, and (b) is explanatory drawing for demonstrating a timing change lottery table. It is explanatory drawing for demonstrating the structure of the sound light side RAM in 81st Embodiment. (A) It is explanatory drawing explaining the structure for performing the external output of the representative value data in 82nd Embodiment, (b) Explaining the storage area for external output of the representative value data in the work area for specific control. It is explanatory drawing for doing. It is a flowchart which shows the external information setting process performed by the main side CPU. 7 is a time chart showing a state in which an abnormality in a base value can be grasped based on representative value data externally output to a data display. (A) It is a block diagram for demonstrating the structure for outputting the machining representative value data to the outside in 83rd Embodiment, (b) The external output of the machining representative value data provided in the work area for specific control. It is an explanatory view for explaining a storage area for. It is a flowchart which shows the external information setting process performed by the main side CPU. (A) It is a block diagram for demonstrating the structure for externally outputting the base value abnormal signal in 84th Embodiment, (b) External output of the base value abnormal signal provided in the work area for specific control. FIG. 3 is an explanatory diagram for explaining a storage area for use with, and (c) an explanatory diagram for explaining the contents of a threshold table. It is a flowchart which shows the external information setting process performed by the main side CPU. It is a flow chart which shows the main processing performed by the master side CPU. 9 is a flowchart showing a base value initial output process executed by the main CPU. 7 is a time chart showing how a base value abnormality signal is externally output to an abnormality alarm device based on an abnormality in a base value in a current area. 7 is a time chart showing how a base value abnormality signal is externally output to an abnormality alarm device based on an abnormality in a base value in the first history area to the third history area. (A) It is a block diagram for demonstrating the structure for externally outputting the upper side base value abnormal signal and the lower side base value abnormal signal in 85th Embodiment, (b) It is provided in the work area for specific control. FIG. 7 is an explanatory diagram for explaining a storage area for external output of an upper base value abnormality signal and a lower base value abnormality signal. It is a flowchart which shows the external information setting process performed by the main side CPU. 7 is a flowchart showing an abnormality flag setting process executed by the main CPU. It is a flowchart which shows the process for abnormal signal output performed by the main side CPU. 9 is a flowchart showing a base value initial output process executed by the main CPU. (A) A storage area for external output of the upper base value abnormality signal, the lower first base value abnormality signal, and the lower second base value abnormality signal, which is provided in the work area for specific control in the 86th embodiment. It is an explanatory view for explaining, (b) is an explanatory view for explaining the contents of a threshold table, and (c) upper base value abnormal signal, lower 1st base value abnormal signal, and 2nd lower base value. It is explanatory drawing for demonstrating the structure for outputting an abnormal signal outside. 7 is a time chart showing how a base value abnormality signal is output to the outside. 7 is a flowchart showing an abnormality flag setting process executed by the main CPU. It is a flowchart which shows the process for abnormal signal output performed by the main side CPU. (A), (b) A block diagram for explaining a configuration for externally outputting a common base value abnormality signal, an upper base value abnormality signal, and a lower base value abnormality signal in the 87th embodiment. It is a flowchart which shows the process for abnormal signal output performed by the main side CPU. It is explanatory drawing for demonstrating the electric constitution of the sound emission control board in the 88th embodiment. It is a flow chart which shows a sound-light side starting processing performed by a sound-light side CPU. It is a flowchart which shows the maximum value setting process performed by (a) sound light side CPU, and (b) is explanatory drawing for demonstrating the maximum value lottery table. It is a flowchart which shows the update process of the timer counter for a demo start performed by the sound side CPU. It is a front view of the main control device in an 89th embodiment. It is an explanatory view for explaining various areas of a work area for non-specific control used for managing a game history. (A) ~ (g) is a time chart showing how the first unit update area, the latest area of the first calculation period, the second unit update area, and the latest area of the second calculation period are updated. (A)-(d) It is explanatory drawing for demonstrating the display content of the 1st-5th notification display apparatus. It is a flowchart which shows the check process performed by the main side CPU. It is a flowchart showing a payout rate storage process executed by the main CPU. 6 is a flowchart showing a display process executed by a main CPU. It is a flow chart which shows the setting processing at the time of normal performed by the side CPU. It is a time chart which shows a mode that "1" is set to (a)-(k) 1st notification start flag and 2nd notification start flag. It is an explanatory view for explaining various areas of a work area for non-specific control used for managing a game history in a 90th embodiment. It is a flowchart showing a payout rate storage process executed by the main CPU. It is a flow chart which shows the 1st payout rate operation processing performed by the main side CPU. It is an explanatory view for explaining various areas of a work area for non-specific control used for managing a game history in the ninety-first embodiment. It is a flowchart showing a payout rate storage process executed by the main CPU. (A), (b) It is explanatory drawing for demonstrating the display content of the 1st, 3rd-5th notification display apparatus in 92nd Embodiment. (A) It is explanatory drawing for demonstrating the various areas of the work area for non-specific control in 93rd Embodiment, (b) The 1st-4th notification in the situation where the total number information is displayed. FIG. 7 is an explanatory diagram for explaining display contents of the display device for display. (A) ~ (e) is a time chart showing how the total number information is displayed on the first to fourth notification display devices. It is a flow chart which shows the 1st timer interruption processing performed by the main side CPU. It is a flow chart which shows the trial shooting test execution processing performed by the main side CPU. It is a flow chart which shows management execution processing performed by a master side CPU. It is a flowchart which shows the check process performed by the main side CPU. It is a flowchart which shows the result calculation process performed by the main side CPU. 7 is a flowchart showing a total number display setting process executed by the main CPU. 6 is a flowchart showing a display process executed by a main CPU. It is a flowchart which shows the process for total number display performed by the main side CPU. It is a flow chart which shows the 2nd timer interruption processing performed by the main side CPU. It is a flowchart which shows the residual process performed by the main side CPU. It is a flow chart which shows total division execution processing performed by a master side CPU. It is a flow chart which shows total division processing performed by the master side CPU. It is a flow chart which shows the 1st timer interruption processing performed by the main side CPU in a 94th embodiment. It is a flow chart which shows the trial shooting test execution processing performed by the main side CPU. It is a flow chart which shows management execution processing performed by a master side CPU. It is a flow chart which shows the 1st timer interruption processing performed by the main side CPU in a 95th embodiment. It is a flow chart which shows management execution processing performed by a master side CPU. (A) It is a front view of the game board in 96th Embodiment, (b) It is explanatory drawing for demonstrating the state of the special figure display part and the general figure display part in the state where the total number display is performed. .. 7 is a flowchart showing a display control process executed by the main CPU. (A) It is explanatory drawing for demonstrating the content of the determination register|resistor in 97th Embodiment, (b) It is explanatory drawing for demonstrating the content of the state specific area. It is a flow chart which shows the main processing performed by the master side CPU. 7 is a flowchart showing an abnormality determination process executed by the main CPU. It is an explanatory view for explaining a storage area of a main side RAM. It is a flow chart which shows blackout information storage processing performed by the main side CPU. It is a flow chart which shows the state setting processing to the judgment register performed by the main side CPU. 7 is a flowchart showing an operation determination process executed by the main CPU. It is a flowchart which shows the residual process performed by the main side CPU. It is a flow chart which shows the 1st timer interruption processing performed by the main side CPU. 7 is a flowchart showing a setting process executed by the main CPU. It is a flow chart which shows the setting corresponding processing performed by the master side CPU. (A) ~ (d) is a time chart showing an execution mode of processing in a situation where processing for changing the setting value or processing for confirming the setting value is being executed. 9A to 9F are time charts showing that in the main processing, the execution of the processing for changing the set value based on the setting change operation is prioritized over the setting of the abnormal state for the occurrence of the abnormality. It is a flow chart which shows command transmission processing at the time of power supply executed by the main side CPU. It is a flow chart which shows the command corresponding processing performed with an audio emission control device. (A) ~ (g) is a time chart showing how a command is transmitted from the main CPU to the sound emission control device when the supply of operating power is started. It is a flowchart which shows the output start process of the security signal performed by (a) main CPU, and the flowchart which shows the security signal corresponding process performed by (b) main CPU. It is a time chart which shows a mode that (a)-(f) security signal is output outside.

<First Embodiment>
Hereinafter, a first embodiment of a pachinko machine 10, which is a type of gaming machine, will be described in detail with reference to the drawings. FIG. 1 is a perspective view of a pachinko machine 10, and FIG. 2 is an exploded perspective view of the main components of the pachinko machine 10. Note that, in FIG. 2, for convenience, the configuration in the game area PA of the pachinko machine 10 is omitted.

As shown in FIG. 1, the pachinko machine 10 includes an outer frame 11 forming an outer shell of the pachinko machine 10, and a gaming machine body 12 rotatably attached to the outer frame 11 forward. Have. The outer frame 11 is formed by connecting wooden plate members to four sides and has a rectangular frame shape. The pachinko machine 10 is installed in the game hall by attaching and fixing the outer frame 11 to the island facility. The outer frame 11 is not an essential component of the pachinko machine 10, and the island frame of the game hall may be equipped with the outer frame 11.

As shown in FIG. 2, the gaming machine main body 12 includes an inner frame 13, a front door frame 14 arranged in front of the inner frame 13, and a back pack unit 15 arranged behind the inner frame 13. ing. The inner frame 13 of the gaming machine body 12 is rotatably supported by the outer frame 11. Specifically, the inner frame 13 is rotatable forward when the left side is the rotation base end side and the right side is the rotation front end side when viewed from the front.

A front door frame 14 is rotatably supported by the inner frame 13, and can be turned forward with the left side as a rotation base end side and the right side as a rotation front end side in a front view. A back pack unit 15 is rotatably supported by the inner frame 13, and is rotatable rearward with the left side being the rotation base end side and the right side being the rotation front end side in front view.

In addition, the gaming machine main body 12 is provided with a locking device at its rotating front end, and has a function of locking the gaming machine main body 12 with respect to the outer frame 11 in a locked state, and The door frame 14 has a function of locking the inner frame 13 so that the door frame 14 cannot be opened. Each of these locked states is released by performing an unlocking operation using the unlocking key on the cylinder lock 17 exposed on the front surface of the pachinko machine 10.

Next, the configuration of the front side of the gaming machine body 12 will be described.

The inner frame 13 is mainly composed of a resin base 21 whose outer shape is substantially the same as that of the outer frame 11. A substantially elliptical window hole 23 is formed in the center of the resin base 21. A game board 24 is detachably attached to the resin base 21. The game board 24 is made of plywood, and the game area PA formed on the front surface of the game board 24 is exposed to the front surface side of the inner frame 13 through the window hole 23 of the resin base 21.

Here, the configuration of the game board 24 will be described with reference to FIG. FIG. 3 is a front view of the game board 24.

An inner rail portion 25 and an outer rail portion 26 are attached to the game board 24 so as to partition a part of the outer edge of the game area PA, and the inner rail portion 25 and the outer rail portion 26 guide the means. The guide rail as is configured. The game ball launched from the game ball launching mechanism 27 (see FIG. 2) attached below the window hole 23 in the resin base 21 is guided by the guide rail to the upper part of the game area PA.

By the way, the game ball launching mechanism 27 includes a launch rail 27a extending toward the guide rail, a ball feeding device 27b for supplying game balls stored in an upper plate 55a described later onto the launch rail 27a, and a launch rail 27a. And a solenoid 27c which is an electric actuator for firing the game ball supplied to the guide rail toward the guide rail. By rotating the firing operation device (or operation handle) 28 provided on the front door frame 14, the solenoid 27c is drive-controlled, and the game ball is fired.

The game board 24 is formed with a plurality of large and small openings penetrating in the front-rear direction. A general winning opening 31, a special electricity winning device 32, a first operating opening 33, a second operating opening 34, a through gate 35, a variable display unit 36, a special drawing unit 37, a universal drawing unit 38, etc. are provided in each opening. ing. A total of four general winning openings 31 are provided, and one is provided for each other.

Even if the ball enters the through gate 35, the payout of the game ball is not executed. On the other hand, when the general winning opening 31, the special electric winning device 32, the first operating opening 33 and the second operating opening 34 occur, a predetermined number of game balls are paid out. Regarding the number of prize balls, specifically, when one game ball enters the first operation port 33 or when one game ball enters the second operation port 34. The payout of one prize ball is executed, and when one game ball is inserted into the general winning opening 31, the payout of ten prize balls is executed and the special prize winning device 32 is displayed. When one of the game balls is entered, the payout of 15 prize balls is executed.

The number of prize balls is arbitrary, and for example, the number of prize balls may be smaller in the second operating port 34 than in the first operating port 33, and the second operating port 34 may be the first operating port. The number of prize balls may be larger than 33.

In addition, an out port 24a is provided at the bottom of the game board 24, and game balls that have not entered various winning ports are discharged from the game area PA through the out port 24a. Further, on the game board 24, a large number of nails 24b are planted in order to appropriately disperse and adjust the falling direction of the game balls, and various members such as a wind turbine are provided.

Here, the entry ball means that the game ball passes through a predetermined opening, and not only the mode in which the game ball is discharged from the game area PA after passing through the opening, but also the game area PA after passing through the opening. A mode in which the game area PA continues to flow down without being discharged is also included. However, in the following description, in order to be clearly distinguished from the game ball entering the outlet 24a, a general prize hole 31, a special electric prize winning device 32, a first operating port 33, a second operating port 34, and a through gate 35. Entering a game ball into is also referred to as a prize.

The first operating port 33 and the second operating port 34 are unitized as an operating port device and installed on the game board 24. Both the first operating port 33 and the second operating port 34 are open upward. Further, the both operating ports 33, 34 are arranged in the vertical direction so that the first operating port 33 faces upward. The second working port 34 is provided with a general electric accessory 34a as a guide piece composed of a pair of left and right movable pieces. In the closed state of the universal electric accessory 34a, the game ball cannot enter the second operating port 34, and when the universal electric object 34a is in the open state, it is possible to enter the second operating port 34.

A through gate 35 is provided on the upstream side of the second operation port 34 in the downflow direction of the game ball. The through gate 35 has a through hole (not shown) penetrating in the vertical direction, and the game ball winning the through gate 35 flows down in the game area PA after winning. As a result, the game ball that has won the through gate 35 can enter the second operating port 34.

Based on the winning of the through-gate 35, the general electric accessory 34a of the second operating port 34 is switched from the closed state to the open state. Specifically, an internal lottery is triggered by winning the prize in the through gate 35, and a public figure display of the general figure unit 38 provided in the lower right corner, which is an area in the game area PA where the game balls do not pass. The variable display of the pattern is performed in the section 38a. Then, when the result of the internal lottery is the electric power combination opening winning, the stop result corresponding to the result is displayed, and the variable display of the universal graphic display portion 38a is ended, the operation shifts to the universal electric open state. In the general electric open state, the general electric accessory 34a is opened in a predetermined manner.

In addition, the general-purpose display unit 38a is composed of a segment display in which a plurality of display segments by LEDs are arranged in a predetermined mode, but the display unit 38a is not limited to this, and a liquid crystal display device, an organic EL device, or the like. It may be configured by other types of display devices such as a display device, a CRT or a dot matrix display. Further, as the pattern variably displayed on the universal figure display unit 38a, a configuration in which a plurality of types of characters are variably displayed, a configuration in which a plurality of types of symbols are variably displayed, a configuration in which a plurality of types of characters are variably displayed, or A configuration in which a plurality of colors are switched and displayed can be considered.

In the universal figure unit 38, a universal figure hold display section 38b is provided at a position adjacent to the universal figure display section 38a. The maximum number of game balls that have won in the through gate 35 is four, and the number of reserved balls is displayed by lighting the universal figure reservation display section 38b.

A winning lottery is carried out with the winning of the first working opening 33 or the second working opening 34 as a trigger. Then, the lottery result is clearly shown through the display effect on the symbol display device 41 of the special drawing unit 37 and the variable display unit 36.

More specifically, the special drawing unit 37 is provided with a special drawing display portion 37a. The display area of the special figure display portion 37a is narrower than the display surface 41a of the symbol display device 41. In the special figure display portion 37a, a winning or lottery is performed with the winning of the first operating opening 33 or the winning of the second operating opening 34 as a trigger, whereby a variable display or a predetermined display of the design is performed. Then, the result corresponding to the lottery result is displayed. The special figure display portion 37a is composed of a segment display in which a plurality of display segments by LEDs are arranged in a predetermined manner, but the invention is not limited to this, and a liquid crystal display device, an organic EL device or the like. It may be configured by other types of display devices such as a display device, a CRT or a dot matrix display. As the picture displayed on the special figure display portion 37a, a plurality of types of characters are displayed, a plurality of types of symbols are displayed, a plurality of types of characters are displayed, or a plurality of types of colors are displayed. A configuration in which is displayed is conceivable.

In the special figure unit 37, a special figure reservation display section 37b is provided at a position adjacent to the special figure display section 37a. The maximum number of game balls that have won in the first operating port 33 or the second operating port 34 is reserved, and the reserved number is displayed by turning on the special figure pending display portion 37b.

In detail about the symbol display device 41, the symbol display device 41 is configured as a liquid crystal display device including a liquid crystal display, and the display content is controlled by a display control device described later. The symbol display device 41 is not limited to the liquid crystal display device, and may be another display device having a display screen such as a plasma display device, an organic EL display device or a CRT, and is a dot matrix display device. May be.

In the symbol display device 41, when the variable display or the predetermined display of the symbol is performed on the special symbol display portion 37a based on the winning of the first operating port 33 or the winning of the second operating port 34, the symbol is displayed in accordance with the variable display. A variable display or a predetermined display is performed. For example, on the display surface 41a of the symbol display device 41, three symbol rows of upper, middle, and lower rows are set as a plurality of display areas, and each of the symbol columns has a number "1" to "9". The symbols are scroll-displayed with the symbols arranged in ascending or descending order. In this scroll display, the scroll display in all the symbol rows is first started, and the scroll display is switched from the scroll display to the standby display in the order of the upper symbol row → the lower symbol row → the middle symbol row, and finally in each symbol row It ends with the pattern still displayed. Then, in the game times in which the game result is a jackpot result, a predetermined combination of symbols is stopped and displayed on the preset effective line on the display surface 41a of the symbol display device 41. Specifically, the same odd symbol combination is stopped and displayed when the most advantageous jackpot result described later is displayed, and the same even symbol combination is stopped and displayed when the low-probability jackpot result described later is displayed. If it is a low winning high certainty jackpot result, it is not the same symbol combination, but if it is not a low winning high certainty jackpot result, the symbol combination that is not stopped and displayed is stopped and displayed.

In addition, in the symbol display device 41, not only the display effect triggered by the winning of the first operation opening 33 or the second operation opening 34, but also the display effect in the opening/closing execution mode which is shifted after the winning is achieved. Be seen. In addition, based on the winning in one of the operation ports 33, 34, the display is started on the special figure display portion 37a and the symbol display device 41, and a predetermined result is displayed and ended until the game time is 1 Equivalent to times. Further, the manner of variable display of the symbols in the symbol display device 41 is not limited to the above, but is arbitrary, and the number of symbol columns, the direction of variable display of symbols in the symbol column, the number of symbols in each symbol column, etc. Can be changed as appropriate. Further, the picture variably displayed on the picture display device 41 is not limited to the above-mentioned picture, and for example, only numbers may be variably displayed as the picture.

When a big hit is won in the winning lottery based on the winning of the first working opening 33 or the winning of the second working opening 34, the opening/closing execution mode in which it is possible to win the special electric prize winning device 32 is performed. The special electric winning device 32 is provided with a big winning opening (not shown) leading to the back side of the game board 24, and an opening/closing door 32a for opening and closing the big winning opening. The open/close door 32a is arranged in either a closed state or an open state. Specifically, the opening/closing door 32a is normally in a closed state in which game balls cannot be won, and when the game is transferred to the open/close execution mode in the internal lottery, the game balls can be switched to an open state in which prizes can be won. It has become. By the way, the opening/closing execution mode is a mode to be shifted to when a winning result is obtained. It should be noted that in the closed state, the winning is not impossible, but the winning state may be less likely to occur than in the opened state.

FIG. 4 is an explanatory diagram for explaining a configuration relating to the discharge of the game balls flowing down the game area PA.

As described above, the game balls that enter the general winning opening 31, the special electricity winning device 32, the first operating opening 33, the second operating opening 34, and the out opening 24a are discharged from the game area PA. In other words, the game ball shot from the game ball launching mechanism 27 and flowing into the game area PA is any one of the general winning opening 31, the special electricity winning device 32, the first operating opening 33, the second operating opening 34, and the outlet 24a. By entering the ball, it will be discharged from the game area PA. The game ball that has entered the general winning opening 31, the special electric winning device 32, the first operating opening 33, the second operating opening 34, or the out opening 24a is guided to the back side of the game board 24.

On the back surface of the game board 24, discharge passage portions 42 to 48 are formed corresponding to the general winning opening 31, the special electric winning device 32, the first operating opening 33, the second operating opening 34, and the out opening 24a. .. The game balls that have flowed into the discharge passages 42 to 48 are guided to the lower end of the game board 24 on the back side of the game board 24 by flowing down the flowed out discharge passages 42 to 48, and to the discharge ball collecting portion (not shown). Be recovered. Then, the game balls collected by the discharge ball collecting section are discharged to the ball circulating device of the island facility in which the pachinko machine 10 is installed in the game hall.

Various detection sensors 42a to 48a for detecting a game ball are provided in the respective discharge passage portions 42 to 48. The discharge passage portions 42 to 48 and the detection sensors 42a to 48a will be described below. Since the four general winning openings 31 are provided as described above, the discharge passage portions 42 to 44 are provided corresponding to each of the four. In this case, one detection sensor 42a is provided for each of the first discharge passage portion 42 corresponding to the leftmost general winning opening 31 and the second discharge passage portion 43 corresponding to the right general winning opening 31 adjacent thereto. 43a is provided. Specifically, the first winning opening detection sensor 42a is provided such that the detection range exists in the middle position of the first discharge passage portion 42, and the detection range is formed in the middle position of the second discharge passage portion 43. The second winning opening detection sensor 43a is provided so as to exist. The game ball that has entered the leftmost general winning opening 31 is detected by the first winning opening detection sensor 42a while passing through the first discharge passage portion 42, and the game that entered the general winning opening 31 on the right side thereof. The ball is detected by the second winning opening detection sensor 43a while passing through the second discharge passage portion 43. Further, a third discharge passage portion 44 formed so as to join at the middle position with respect to the two right general winning openings 31 is provided. The third discharge passage portion 44 has an entrance side area corresponding to each of the two general winning openings 31, and also has one exit side area due to the entrance side areas joining in the middle. doing. The third winning opening detection sensor 44a is provided so that the detection range exists at an intermediate position of the outlet side region of the third discharge passage portion 44. The game ball that has entered one of the two right winning openings 31 on the right side is detected by the third winning opening detection sensor 44a while passing through the third discharge passage portion 44.

The fourth discharge passage portion 45 is provided so as to correspond to the special electric winning device 32. The special electricity detection sensor 45a is provided so that the detection range exists at the midway position of the fourth discharge passage portion 45, and the game ball entering the special electricity prize winning device 32 is in the middle of passing through the fourth discharge passage portion 45. It is detected by the special electric detection sensor 45a. The fifth discharge passage portion 46 is provided so as to correspond to the first operation port 33. The first working port detection sensor 46a is provided so that the detection range is present at an intermediate position of the fifth discharging passage portion 46, and the game sphere that has entered the first working opening 33 moves through the fifth discharging passage portion 46. During the passage, it is detected by the first working port detection sensor 46a. The sixth discharge passage portion 47 is provided so as to correspond to the second operation port 34. The second working port detection sensor 47a is provided so that the detection range exists in the middle of the sixth discharging passage part 47, and the game ball entering the second working port 34 moves through the sixth discharging passage part 47. During the passage, it is detected by the second working port detection sensor 47a. The seventh discharge passage portion 48 is provided so as to correspond to the outlet 24a. The outlet detection sensor 48a is provided so that the detection range exists in the middle of the seventh discharge passage portion 48, and the game ball entering the outlet 24a is in the middle of passing through the seventh discharge passage portion 48. It is detected by the outlet detection sensor 48a.

In addition, the game ball detected by any one of the various detection sensors 42a to 48a will not be detected by the other detection sensors 42a to 48a. Further, a gate detection sensor 49a is also provided for the through gate 35, and a game ball passing through the through gate 35 while flowing down the game area PA is detected by the gate detection sensor 49a.

An electromagnetic induction type proximity sensor is used as each of the various detection sensors 42a to 49a, but any sensor can be used as long as it can individually detect a game ball. Further, the various detection sensors 42a to 49a are electrically connected to a main control device 60 described later, and the detection results of the various detection sensors 42a to 49a are output to the main control device 60. Specifically, the various detection sensors 42a to 49a output a LOW level signal when the game ball is not detected, and output a HI level signal when the game ball is detected. The relationship between HI and LOW is not limited to this, and may be reversed.

As shown in FIG. 2, the front door frame 14 is provided so as to cover the entire front surface side of the inner frame 13 in which the game board 24 having the above configuration is attached to the resin base 21. As shown in FIG. 1, the front door frame 14 is provided with a window portion 51 that allows almost the entire game area PA to be viewed from the front. The window 51 has a substantially elliptical shape, and a window panel 52 is fitted therein. The window panel 52 is made of glass and is colorless and transparent, but the present invention is not limited to this, and it may be made of synthetic resin and is colorless and transparent, and the game area PA is provided from the front of the pachinko machine 10 through the window panel 52. If it is visible, it may be formed to be colored and transparent.

A display light emitting portion 53 is provided above the window portion 51. Further, a pair of left and right speaker units 54 for outputting a sound effect according to the game state are provided. Further, below the window portion 51, an upper bulge portion 55 and a lower bulge portion 56 which bulge toward the front side are arranged in parallel vertically. An upper plate 55a that opens upward is provided inside the upper bulging portion 55, and a lower plate 56a that also opens upward is provided inside the lower bulging portion 56. The upper plate 55a has a function of temporarily storing the game balls paid out from a payout device described later and guiding them to the game ball launching mechanism 27 side while aligning them in a line. In addition, the lower plate 56a has a function of storing game balls that have become redundant in the upper plate 55a.

Next, the configuration of the back side of the gaming machine body 12 will be described.

As shown in FIG. 2, on the back surface of the inner frame 13 (specifically, the game board 24), a main controller 60 that controls the main control of the game is mounted. FIG. 5 is a front view of main controller 60.

As shown in FIG. 5, the main controller 60 has a main control board 61 housed in a board box 60a. The MPU 62 is mounted on the element mounting surface, which is one plate surface of the main control board 61. The board box 60a is formed transparent so that the MPU 62 housed in the board box 60a can be viewed from the outside of the board box 60a. Although the substrate box 60a is formed to be colorless and transparent, it may be formed to be colored and transparent as long as the MPU 62 accommodated in the substrate box 60a can be viewed from the outside of the substrate box 60a. The main controller 60 is mounted on the back surface of the resin base 21 so that the facing wall portion 60b facing the element mounting surface of the main control board 61 in the board box 60a faces the rear of the pachinko machine 10. Therefore, by opening the gaming machine main body 12 to the front of the pachinko machine 10 with respect to the outer frame 11 to expose the back surface of the resin base 21, it becomes possible to visually recognize the facing wall portion 60b of the board box 60a. The MPU 62 can be viewed through the facing wall portion 60b.

The board box 60a is formed by combining a plurality of case bodies 60c in the front and back. The plurality of case bodies 60c prevent separation of the case bodies 60c and traces of the case bodies 60c when they are separated. Is provided with a coupling portion 60e for leaving. A plurality of coupling portions 60e are arranged in parallel on one side of the substantially rectangular parallelepiped substrate box 60a. Accordingly, even if the case body 60c is separated by destroying the part of the joint portion 60e while the separation of the case body 60c is prevented by using the part of the joint portion 60e, another joint is performed after that. By separating the part 60e, the case body 60c can be prevented from being separated again. Further, when the case body 60c is separated, the joint portion 60e is destroyed and a trace thereof remains, so that it is possible to visually confirm the joint portion 60e to grasp whether or not the case body 60c is illegally separated. It will be possible. Further, a seal sticker 60f is attached to one side of the substrate box 60a opposite to one side where the coupling portions 60e are arranged in parallel so as to straddle the boundary between the case bodies 60c. When the sealing seal 60f is peeled off, the adhesive layer remains on the case body 60c. As a result, when the sealing seal 60f is peeled off when the case body 60c is separated, the trace can be left.

In the main control device 60 having the above-mentioned configuration, the main control board 61 is owned by the manager of the game hall in order to generate an opportunity to change the setting state of the pachinko machine 10 in the range of "setting 1" to "setting 6". A setting key insertion portion 68a that is turned on by inserting a setting key, an update button 68b that is operated to sequentially change the setting state of the pachinko machine 10 after the setting key insertion portion 68a is turned on, and a main controller. A reset button 68c operated to clear data of a main RAM 65 described later provided in the MPU 62 of 60, and first to third notification display devices 69a to 69c for notifying a game history management result. , Are provided. Further, the MPU 62 mounted on the main control board 61 is connected to the connection terminal of the external device in order to read the management result of the game history or the information (program and data) stored in the main ROM 64 by the external device. A reading terminal 68d is provided for reading. The setting state of the pachinko machine 10 is not limited to the six stages of "setting 1" to "setting 6", and any number of stages can be set.

The setting key insertion portion 68a, the update button 68b, the reset button 68c, the reading terminal 68d (that is, the MPU 62), and the first to third notification display devices 69a to 69c are all provided on the element mounting surface of the main control board 61. ing. The element mounting surface of the main control board 61 faces the facing wall portion 60b of the board box 60a as described above, but the setting key insertion portion 68a, the update button 68b, the reset button 68c, and the reading terminal 68d face each other. It is not covered by the wall 60b. That is, in the facing wall portion 60b, the areas facing the setting key insertion portion 68a, the update button 68b, the reset button 68c, and the reading terminal 68d are individual openings. As a result, the setting key can be inserted into the setting key insertion portion 68a without pressing the board box 60a, the update button 68b can be pressed, and the reset button 68c can be pressed. It is possible to connect the connection terminal of the external device to the reading terminal 68d.

By inserting the setting key into the setting key inserting section 68a and rotating the setting key in a predetermined direction, the setting key inserting section 68a is turned on. It is possible to change the setting state of the pachinko machine 10 by starting the supply of the operation power to the pachinko machine 10 in that state (that is, by starting the supply of the operation power to the MPU 62 of the main controller 60). It becomes possible to change. Then, each time the update button 68b is pressed once in this state, the setting state of the pachinko machine 10 is changed step by step in the ascending order within the range of "setting 1" to "setting 6". When the update button 68b is operated in the state of "setting 6", the setting is updated to "setting 1". In addition, by rotating the setting key inserted in the setting key insertion portion 68a in the direction opposite to the predetermined direction from the position of the ON operation and returning it to the initial position, the setting key insertion portion 68a is turned OFF. Become. When the setting key insertion portion 68a is turned off, the changeable state ends, and the game can be played in the state of the set value at that time. That is, the set value cannot be changed even if the update button 68b is operated after the changeable state ends.

The ON operation to the setting key insertion portion 68a is valid only when the supply of the operating power to the pachinko machine 10 is started (that is, when the supply of the operating power to the MPU 62 of the main control device 60 is started). Therefore, even if the MPU 62 of the main control device 60 performs an ON operation on the setting key insertion portion 68a after the processing at the start of supplying the operating power is completed, the setting value cannot be changed.

The setting state of the pachinko machine 10 determines the degree of advantage per unit time in the pachinko machine 10, and the larger the value of n in the “setting n” (n is an integer of “1” to “6”) (that is, the setting). The higher the value, the higher the advantage. Although details will be described later, there are a low-probability mode in which the winning probability is relatively low and a high-probability mode in which the winning probability is relatively high as win/loss lottery modes for determining the winning probability of the jackpot result, and the set value is The higher the probability, the higher the winning probability of the jackpot result in the low probability mode is set. On the other hand, the winning probability of the jackpot result in the high-probability mode is constant regardless of the set value.

The reset button 68c is operated to clear the data in the main RAM 65 as described above, but in order to generate the clearing of the data, the reset button 68c is pressed to supply the operating power to the pachinko machine 10. Must be started (that is, the supply of operating power to the MPU 62 of the main controller 60 must be started). The ON operation to the reset button 68c is valid only when the supply of the operating power to the pachinko machine 10 is started (that is, when the supply of the operating power to the MPU 62 of the main controller 60 is started). Therefore, even if the reset button 68c is pressed after the process at the time of starting the supply of the operating power in the MPU 62 of the main controller 60 is completed, the data in the main RAM 65 cannot be cleared.

As described above, the reading terminal 68d is connected to the connection terminal of the external device in order to read the game history management result or the information (program and data) stored in the main ROM 64 by the external device. In order to perform the external output to the pachinko machine 10 in the state where the connection terminal of the external device is connected to the reading terminal 68d (that is, the operation of the main controller 60 to the MPU 62 is required). It is necessary to start the power supply). The connection of the external device to the reading terminal 68d is valid only when the supply of the operating power to the pachinko machine 10 is started (that is, when the supply of the operating power to the MPU 62 of the main controller 60 is started). Therefore, even if an external device is connected to the reading terminal 68d after the process at the start of supplying the operating power is completed in the MPU 62 of the main control device 60, the external output to the external device is not performed.

Each of the first to third notification display devices 69a to 69c is a segment display in which seven display segments by LEDs are arranged, but the present invention is not limited to this, and a single multicolor light emission type is provided. It may be a light emitting body, a liquid crystal display device, or an organic EL display. Each of the first to third notification display devices 69a to 69c is installed so that the display surface thereof faces the direction in which the element mounting surface of the main control board 61 faces, and the opposing wall portion 60b of the board box 60a is used. Is covered. In this case, since the substrate box 60a is formed transparent, the display surfaces of the first to third notification display devices 69a to 69c housed in the substrate box 60a are visually observed from the outside of the substrate box 60a. It becomes possible. Further, as already described, the main controller 60 is mounted on the back surface of the resin base 21 so that the facing wall portion 60b facing the element mounting surface of the main control board 61 in the board box 60a faces the rear of the pachinko machine 10. Therefore, when the gaming machine main body 12 is opened to the front of the pachinko machine 10 with respect to the outer frame 11 to expose the back surface of the resin base 21 to the front of the pachinko machine 10, the first to third notifications are made through the facing wall portion 60b. The display surfaces of the display devices 69a to 69c can be visually checked.

On the display surface of the first notification display device 69a, not only the numbers "0" to "9" but also various characters including alphabetic characters are displayed. On the other hand, the numbers 0 to 9 are displayed on the second notification display device 69b and the third notification display device 69c. The management results of the game history are notified using the first to third notification display devices 69a to 69c, and the contents of this notification will be described in detail later. Further, in the changeable state in which the setting state of the pachinko machine 10 can be changed, the value corresponding to the current setting value is displayed on the third notification display device 69c. The value corresponding to the set value may be displayed on the first notification display device 69a or may be displayed on the second notification display device 69b. Further, the set value before the changeable state is displayed on one of the first to third notification display devices 69a to 69c, and the current setting value is set to the first to third notifications. It may be configured to be displayed on another one of the notification display devices 69a to 69c.

As shown in FIG. 2, the back pack unit 15 is installed so as to cover the back side of the inner frame 13 including the main controller 60. The back pack unit 15 includes a back pack 72 formed of a transparent synthetic resin, and the payout mechanism unit 73 and the control device assembly unit 74 are attached to the back pack 72.

The payout mechanism unit 73 includes a tank 75 to which game balls supplied from the island facility of the game hall are sequentially replenished, and a payout device 76 for paying out the game balls stored in the tank 75. The game ball paid out from the payout device 76 is discharged to the upper plate 55a or the lower plate 56a through a payout passage provided on the downstream side of the payout device 76. The payout mechanism unit 73 is provided with a main power supply of, for example, 24 V AC, and a back pack substrate having a power switch for performing ON and OFF operations of the power supply.

The control device gathering unit 74 generates and outputs a payout control device 77 having a function of controlling the payout device 76, a predetermined electric power required by various control devices and the like, and accompanies the player's operation of the firing operation device 28. It is provided with a power supply/launching control device 78 for controlling the launch of a game ball. The payout control device 77 and the power supply/launch control device 78 are arranged in front and back so that the payout control device 77 is behind the pachinko machine 10.

<Electrical configuration of the pachinko machine 10>
FIG. 6 is a block diagram showing the electrical configuration of the pachinko machine 10.

The main controller 60 includes a main control board 61 that controls the main game, and a power failure monitor board 67 that monitors the power supply. An MPU 62 is mounted on the main control board 61. The MPU 62 contains a main side ROM 64, a main side RAM 65, and a management IC 66 in addition to the main side CPU 63, which is an arithmetic processing unit including a control unit and an arithmetic unit. In addition to the above-described elements, the MPU 62 contains an interrupt circuit, a timer circuit, a data input/output circuit, various counter circuits as a random number generator, and the like.

The main-side ROM 64 is a memory such as a NOR flash memory and a NAND flash memory that does not require external power supply for storage storage (that is, a non-volatile storage unit), and is used as a read-only memory. The main ROM 64 stores various control programs executed by the main CPU 63 and fixed value data.

The main RAM 65 is a memory (that is, a volatile storage means) such as an SRAM and a DRAM that needs power supply from the outside to retain the storage, and is used for both reading and writing. The main RAM 65 can be randomly accessed and has a shorter read time than the main ROM 64 when compared with the same data capacity. The main RAM 65 temporarily stores various data and the like for execution of the control program stored in the main ROM 64.

The management IC 66 is a management device that manages the game history based on the information supplied from the main CPU 63. Although the details will be described later, while the management IC 66 grasps the entry history of the game ball into the general winning opening 31, the special electric winning device 32, the first operating opening 33, the second operating opening 34, and the out opening 24a, The frequency of entering the general winning opening 31, the special electric winning device 32, the first operating opening 33, and the second operating opening 34 is ascertained according to the obtained winning history. Further, the management IC 66 grasps the occurrence frequencies of the open/close execution mode and the high-frequency support mode described later.

The MPU 62 is provided with an input port and an output port, respectively. To the input side of the MPU 62, the power failure monitoring board 67 and the payout controller 77 provided in the main controller 60 are connected. A power supply/launch control device 78 having a function of supplying operating power is connected to the power failure monitoring board 67, and operating power is supplied to the MPU 62 via the power failure monitoring board 67.

Various sensors such as the ball detection sensors 42a to 49a are connected to the input side of the MPU 62. As described above, each of the ball detection sensors 42a to 49a has the first winning opening detection sensor 42a, the second winning opening detection sensor 43a, the third winning opening detection sensor 44a, the special electricity detection sensor 45a, and the first working opening detection. The sensor 46a, the second operation port detection sensor 47a, the out port detection sensor 48a, and the gate detection sensor 49a are included. Based on the detection results of these ball detection sensors 42a to 49a, the main CPU 63 determines whether or not each ball has entered the ball. In the main CPU 63, various kinds of lottery are executed based on the winning of the first operating opening 33, and various kinds of drawing are executed based on the winning of the second operating opening 34.

On the input side of the MPU 62, a setting key insertion section 68a provided on the main control board 61, an update button 68b and a reset button 68c are provided. The setting key insertion portion 68a is provided with a sensor (not shown), and the sensor detects whether the setting key insertion portion 68a is arranged in the ON operation position or the OFF operation position. Then, the main CPU 63 identifies whether the setting key insertion portion 68a is arranged at the ON operation position or the OFF operation position based on the detection result from the sensor. The update button 68b is provided with a sensor (not shown), and the sensor detects whether or not the update button 68b is pressed. Then, the main CPU 63 specifies whether or not the update button 68b is pressed based on the detection result from the sensor. The reset button 68c is provided with a sensor (not shown), and the sensor detects whether or not the reset button 68c is pressed. Then, the main CPU 63 specifies whether or not the reset button 68c is pressed based on the detection result from the sensor.

A power failure monitoring board 67, a payout control device 77, and a voice emission control device 81 are connected to the output side of the MPU 62. In the payout control device 77, for example, a prize ball command is output based on the fact that a game ball has entered a prize ball-corresponding ball part in which the occurrence of a ball corresponds to the payout of a game ball in the ball entering part. It Various commands such as a variation command, a type command, and an opening command are output to the sound emission control device 81.

On the output side of the MPU 62, a special electric drive unit 32b that opens and closes the opening and closing door 32a of the special electric prize winning device 32, a general electric drive unit 34b that opens and closes the general electric officer 34a of the second operation port 34, and The drawing unit 37 and the universal drawing unit 38 are connected. By the way, the special figure unit 37 is provided with a special figure display section 37a and a special figure reservation display section 37b, all of which are connected to the output side of the MPU 62. Similarly, the universal figure unit 38 is provided with a universal figure display section 38a and a universal figure hold display section 38b, all of which are connected to the output side of the MPU 62. Various driver circuits are provided on the main control board 61, and the MPU 62 executes drive control of various drive units and various display units through the driver circuits.

That is, in the opening/closing execution mode, the drive control of the drive unit 32b for special electricity is executed in the main CPU 63 so that the special electricity winning device 32 is opened and closed. In addition, when the general electric outlet object 34a is in the open state, the main CPU 63 executes drive control of the general electric outlet 34b so that the general electric outlet object 34a is opened and closed. Further, at the time of each game, the main CPU 63 executes the display control of the special figure display portion 37a. Further, in the case of clearly indicating the lottery result of whether or not to open the general electric accessory 34a, the main CPU 63 executes the display control of the general figure display unit 38a. Further, when a prize is generated in the first operation port 33 or the second operation port 34, or when the variable display is started on the special figure display unit 37a, the main CPU 63 controls the display of the special figure hold display unit 37b. When the winning is generated in the through gate 35, or when the variable display is started on the general figure display section 38a, the main CPU 63 executes the display control of the general figure hold display section 38b.

First to third notification display devices 69a to 69c are connected to the output side of the MPU 62. Further, the management result of the game history in the management IC 66 is notified through the display on the first to third notification display devices 69a to 69c. Further, when the setting state of the pachinko machine 10 is changed, the current set value is displayed on the third notification display device 69c. In this case, the first notification display device 69a and the second notification display device 69b are controlled by the management IC 66 and not controlled by the main CPU 63, whereas the third notification display device 69c is controlled by the main CPU 63. The display is controlled and the display is controlled by the management IC 66. Regarding the display of the third notification display device 69c, the display control by the main CPU 63 has priority over the display control by the management IC 66.

However, the configuration is not limited to this, and the third notification display device 69c may have a configuration in which the display is controlled by the management IC 66 and not controlled by the main CPU 63. In this case, when the current setting value is displayed on the third annunciating display device 69c when the setting state of the pachinko machine 10 is changed, the main CPU 63 instructs the management IC 66 to display the setting value. Good.

The MPU 62 is provided with a reading terminal 68d. The reading terminal 68d is provided with a sensor (not shown), and the sensor detects whether or not the connecting terminal of the external device is connected to the reading terminal 68d. Then, the main CPU 63 specifies whether the connection terminal of the external device is connected to the reading terminal 68d based on the detection result from the sensor. When an external device is connected to the reading terminal 68d, the management result of the game history in the management IC 66 or the information (program and data) stored in the main ROM 64 is output to the external device.

The power failure monitoring board 67 relays the main control board 61 and the power supply/launch control device 78 and monitors the voltage of DC stable 24V which is the maximum voltage output from the power supply/launch control device 78. The payout control device 77 controls the payout device 76 to pay out prize balls or loan balls based on the prize ball command received from the main control device 60.

The power supply/launch control device 78 is connected to, for example, a commercial power supply (external power supply) in a game hall or the like. Then, based on the external power supplied from the commercial power source, the main control board 61, the payout control device 77, and the like are generated with necessary operating power, and the generated operating power is supplied. By the way, the power supply/launch control device 78 is provided with a power supply unit for power interruption such as a backup capacitor, and even when the power of the pachinko machine 10 is in the OFF state, the power supply unit for power interruption is mainly used. Electric power for storage is supplied to the main RAM 65 of the control device 60 and the payout control device 77. The power supply/launch control device 78 is responsible for the launch control of the game ball launch mechanism 27, and the game ball launch mechanism 27 is driven when a predetermined launch condition is satisfied. Further, the payout mechanism unit 73 is provided with the power switch as already described, and when the power switch is turned on, supply of operating power to the pachinko machine 10 is started and the power switch is turned off. As a result, the supply of operating power to the pachinko machine 10 is stopped.

The sound emission control device 81 drives and controls the display light emission part 53 and the speaker part 54 provided on the front door frame 14 and controls the display control device 82 based on various commands received from the main control device 60. Is. The display control device 82 executes the display control of the symbol display device 41 based on the command received from the voice emission control device 81.

<Electrical configuration for performing various lottery in the main CPU 63>
Next, an electrical configuration for the main CPU 63 to perform various kinds of lottery will be described with reference to FIG.

The main CPU 63 uses a variety of counter information at the time of the game to perform jackpot occurrence lottery, setting of display of the special symbol display portion 37a, setting of symbol display of the symbol display device 41, setting of display of the general symbol display portion 38a, etc. Specifically, as shown in FIG. 7, the winning random number counter C1 used for the lottery for winning, the jackpot type counter C2 used when determining the jackpot type, and the symbol display device 41 are displaced. Reach random number counter C3 used for reach generation lottery when performing, random number initial value counter CINI used for initial value setting of the hit random number counter C1, and display duration in the special figure display portion 37a and the symbol display device 41 are determined. The fluctuation type counter CS is used. Further, the universal electric accessory opening counter C4 used in a lottery for determining whether or not to put the ordinary electric accessory 34a of the second operation port 34 in the ordinary electric open state is used. The counters C1 to C3, CINI, CS and C4 are provided in various counter areas 65b of the main RAM 65.

Each of the counters C1 to C3, CINI, CS, and C4 is a loop counter in which 1 is added to the previous value each time it is updated, and after reaching the maximum value, it returns to "0". Each counter is updated at short time intervals. The information corresponding to the winning random number counter C1, the jackpot type counter C2, and the reach random number counter C3 is provided as acquisition information storage means in the main RAM 65 when a prize is awarded to the first operating opening 33 or the second operating opening 34. It is stored in the reserved storage area 65a.

The hold storage area 65a includes a hold area RE and an execution area AE. The holding area RE includes a first holding area RE1, a second holding area RE2, a third holding area RE3, and a fourth holding area RE4, and the winning history of the first working opening 33 or the second working opening 34 is recorded. In addition, a combination of numerical value information of the hit random number counter C1, the big hit type counter C2, and the reach random number counter C3 is stored in any of the holding areas RE1 to RE4 as holding information.

In this case, in the first holding area RE1 to the fourth holding area RE4, when the winnings to the first working opening 33 or the second working opening 34 occur successively a plurality of times, the first holding area RE1→the second holding area RE1 Numerical information is stored in chronological order in the order of the holding area RE2→the third holding area RE3→the fourth holding area RE4. Since the four holding areas RE1 to RE4 are provided in this way, the winning history of the game balls to the first working opening 33 or the second working opening 34 can be held and stored up to a maximum of four. ..

Note that the number that can be reserved and stored is not limited to four and may be any number, and may be another number such as two, three, or five or more, or may be a single number.

The execution area AE is an area for moving each numerical value information stored in the first holding area RE1 of the holding area RE when starting the variable display of the special figure display portion 37a, and starts one game time. At that time, a win/fail judgment is made based on various numerical information stored in the execution area AE.

Each of the above counters will be described in detail.

First, the general electric accessory opening counter C4 will be described. The general electric accessory release counter C4 is configured to be incremented by 1 in the range of 0 to 250, for example, and return to "0" after reaching the maximum value. The ordinary electric accessory release counter C4 is periodically updated and is stored in the ordinary electric current holding area 65c of the main RAM 65 at the timing when the game ball wins the through gate 35. Then, at a predetermined timing, a lottery is performed as to whether or not to control the general electric utility object 34a in the open state based on the stored value of the general electric utility object release counter C4.

In this pachinko machine 10, a plurality of types of support modes are set so that the modes of support by the general electric accessory 34a are different from each other. Specifically, in the support mode, when compared with the situation in which the game balls are continuously emitted in the same manner in the game area PA, the universal utility object 34a of the second working port 34 is opened per unit time. The high frequency support mode and the low frequency support mode are set so that the frequency of the state becomes relatively high and low.

In the high-frequency support mode and the low-frequency support mode, the probability of winning the general electric open state in the general electric open lottery using the general electric accessory release counter C4 is the same (for example, both are 4/5). In the high frequency support mode, the number of times that the general electric outlet 34a is in the open state when the general electric open state is won is set to be larger than that in the low frequency support mode, and the opening time of one time is set longer. Has been done. In this case, in the high-frequency support mode, the general electric open state is won, and when the general electric auditors a thing 34a is opened a plurality of times, from the end of one open state to the start of the next open state. The closing time is set shorter than one opening time. Furthermore, in the high-frequency support mode, the minimum securing time (that is, in the general map The one-time display duration on the display section 38a is set to be short.

As described above, in the high frequency support mode, the probability of winning the second operation opening 34 is higher than in the low frequency support mode. In other words, in the low frequency support mode, the probability of winning a prize in the first operation port 33 is higher than in the second operation port 34, but in the high frequency support mode, the second operation is performed more than the first operation port 33. The probability of winning a prize in the mouth 34 increases. Then, when a winning is generated in the second operating port 34, a predetermined number of game balls are paid out, so in the high frequency support mode, the player plays the game while not reducing the number of balls that he or she holds. It can be carried out.

The configuration for increasing the frequency of the high frequency support mode per unit time to the normal power open state more than the low frequency support mode is not limited to the above-mentioned one. It may be configured to increase the probability that the ordinary electric open state wins. In addition, a securing time that is secured when the next ordinary electric train open lottery is performed after the first ordinary electric train open lottery is performed (for example, it is executed in the universal map display portion 38a based on the winning of the through gate 35). In a configuration in which multiple types of variable display time) are provided, the high-frequency support mode is set so that a shorter securing time can be selected more easily or the average securing time is shorter than in the low-frequency support mode. Good. Furthermore, the number of times of opening is increased, the time of opening is lengthened, and the securing time that is secured when the next ordinary electric train opening lottery is performed after one ordinary electric train opening lottery is shortened. The advantage of the high frequency support mode over the low frequency support mode may be increased by applying any one condition or a condition of any combination of shortening the averaging time and increasing the winning probability.

Here, as described above, the setting states of “setting 1” to “setting 6” exist in the pachinko machine 10, but which is the opening frequency and the opening mode of the general electric officer 34a in the low frequency support mode? The setting values are the same, and the opening frequency and the opening mode of the general electric auditors article 34a in the high frequency support mode are the same regardless of the setting values. However, the present invention is not limited to this, and at least one of the opening frequency and the opening mode of the general electric officer 34a varies depending on the setting state of the pachinko machine 10 in at least one of the low frequency support mode and the high frequency support mode. It may be configured. For example, the higher the set value is, the higher the frequency of opening the general electric outlet 34a in the low frequency support mode may be, and the second operation in the case where the general electric outlet 34a is in the open state once in the low frequency support mode. The probability that the game ball enters the mouth 34 may be increased. Further, the higher the set value is, the higher the frequency of opening the general electric utility article 34a in the high frequency support mode may be. The second case when the general electric utility article 34a is in the open state once in the high frequency support mode may be adopted. It may be configured such that the probability of a game ball entering the actuation opening 34 increases.

Next, the winning random number counter C1 will be described. The hit random number counter C1 is configured to be sequentially incremented by 1 in the range of 0 to 599, for example, and returned to "0" after reaching the maximum value. In particular, when the hit random number counter C1 makes one round, the value of the random number initial value counter CINI at that time is read as the initial value of the hit random number counter C1. The random number initial value counter CINI is a loop counter similar to the random number counter C1 (value=0 to 599). The hit random number counter C1 is regularly updated and is stored in the reserved storage area 65a of the main RAM 65 at the timing when the game ball wins the first operation opening 33 or the second operation opening 34.

The value of the random number that wins the jackpot is stored in the main ROM 64 as a win/loss table. FIG. 8 is an explanatory diagram for explaining various tables stored in the main ROM 64. As the win/loss tables, low probability win/loss tables 64a to 64f for the low probability mode and high accuracy win/loss table 64g for the high probability mode are stored.

The low probability hit/miss tables 64a to 64f are provided in a one-to-one correspondence with the setting states of "setting 1" to "setting 6". That is, the low probability table 64a for setting 1 referred to when the setting state of the pachinko machine 10 is "setting 1", and the setting referred to when the setting state of the pachinko machine 10 is "setting 2". 2 low probability table 64b, the low probability table 64c for setting 3 referred to when the setting state of the pachinko machine 10 is "setting 3", and the setting state of the pachinko machine 10 is "setting 4". When the setting state of the pachinko machine 10 is “Setting 5”, the low probability table 64d for setting 4 referred to when the pachinko machine 10 and the pachinko machine 10 are set. And the low probability table 64f for the setting 6 referred to when the setting state of “setting 6” is “setting 6”.

These low certainty win/loss tables 64a to 64f are set so that the higher the set value, the higher the winning probability of the jackpot result. Specifically, when the low-probability/probability table 64a for setting 1 is referenced, a big hit result is obtained at about 1/320, and when the low-probability/probability table 64b for setting 2 is referenced, about 1/310. Results in a big hit, and when the low probability table 64c for setting 3 is referenced, the result is about 1/300. When the low accuracy table 64d for setting 4 is referenced, the result is approximately 1/290. Results in a big hit, about 1/280 when the low probability table 64e for setting 5 is referred to, and about 1/270 when a low accuracy table 64f for setting 6 is referred to. Will result in a big hit. As a result, when the setting state of the pachinko machine 10 is a high setting value, a jackpot result is more likely to occur in the low-probability mode, which is advantageous for the player.

On the other hand, the high-probability hit/miss table 64g is provided in only one type so as to be common in any of the setting states of “setting 1” to “setting 6”. The high-probability win/loss table 64g is set so that the winning probability of the jackpot result is higher than that of the low-probability win/loss tables 64a to 64f in any of the setting states of "setting 1" to "setting 6". Specifically, when the highly accurate hit/miss table 64g is referred to, the result is a big hit with about 1/30. As a result, it is possible to make the high-probability mode more advantageous than the low-probability mode regardless of the setting state of the pachinko machine 10. In addition, even in the lowest setting state "setting 1", the probability of a jackpot result can be made higher than in the low probability mode of "setting 6" which is the highest setting state by being in the high probability mode. Becomes Further, in the high-probability mode, it is possible to prevent advantages or disadvantages due to the setting state of the pachinko machine 10, and to suppress the storage capacity for storing the high-accuracy/probability table 64g in the main ROM 64 in advance. It becomes possible.

The jackpot type counter C2 is configured to be sequentially incremented by 1 within a range of 0 to 29, and returned to "0" after reaching the maximum value. The jackpot type counter C2 is regularly updated and is stored in the reserved storage area 65a at the timing when the game ball wins the first operating opening 33 or the second operating opening 34.

In this pachinko machine 10, a plurality of jackpot results are set. These plural jackpot results are (1) a mode of the opening/closing control of the special electric prize winning device 32 in the opening/closing execution mode, (2) a lottery mode in the winning/losing lottery means after the completion of the opening/closing execution mode, and (3) a result after the completion of the opening/closing execution mode. A plurality of jackpot results are set by providing differences in the three conditions, that is, the support mode in the universal electric accessory 34a of the 2 working port 34.

As an aspect of the opening/closing control of the special electric prize winning device 32 in the opening/closing execution mode, the high frequency is set so that the frequency of winning the special electric winning device 32 from the start to the end of the opening/closing execution mode is relatively high. A frequency winning mode and a low frequency winning mode are set. Specifically, in either the high frequency winning mode or the low frequency winning mode, the round game of a predetermined number of times is executed as an upper limit.

A round game is a game that continues until a predetermined upper limit duration period elapses, or a predetermined upper limit number of game balls are won in the special electric prize winning device 32 until either condition is satisfied. That is. Further, the number of round games in the opening/closing execution mode triggered by the jackpot result is the same as the fixed round number regardless of the type of the jackpot result triggered by the transition. Specifically, no matter which jackpot result is obtained, the upper limit number of round games is set to 15 rounds.

Further, in the pachinko machine 10, a plurality of types are set for the one-time opening mode of the special electric prize winning device 32, with different open durations from the opening of the special electric winning device 32 to the closing. Specifically, a long time mode in which the open duration is set to 29 seconds, which is a long time, and a short time mode in which the open duration is set to 0.06 seconds, which is a short time shorter than the above long time, Is set.

In the pachinko machine 10, in a situation where the firing operation device 28 is operated by the player, the game ball launching mechanism 27 is driven so that one game ball is launched toward the game area PA in 0.6 seconds. Controlled. Further, the upper limit number of end conditions for the round game is set to nine. Then, in the long time mode of the above-mentioned opening modes, the opening continuation time that is longer than the product of the firing cycle of the game ball and one round game is set. On the other hand, in the short time mode, a time shorter than the product of the firing cycle of the game ball and one round game, more specifically, a release duration of a time shorter than the firing cycle of the game ball is set. Therefore, when the opening is performed once in the long time mode, it is expected that the special electric prize winning device 32 will be won by the upper limit number in one round game. When the opening is performed twice, it is expected that no prize will be paid to the special electric prize winning device 32, or that even if a prize is generated, it will be about one.

In the high frequency winning mode, the special electric winning device 32 is opened once for a long time in each round game. On the other hand, in the low frequency winning mode, the special electric winning device 32 is opened once in each round game in a short time mode.

In addition, the number of times the special electric winning device 32 is opened/closed in the high frequency winning mode and the low frequency winning mode, the number of round games, the opening duration for one opening, and the upper limit number of one round game are the ones in the high frequency winning mode. Is not limited to the above value, as long as the frequency of winning the special electric prize winning device 32 from the start to the end of the opening/closing execution mode is higher than that in the low frequency winning mode. Is.

The distribution destination of the jackpot result to the jackpot type counter C2 is stored in the main ROM 64 as a distribution table 64h, as shown in FIG. Then, in the distribution table 64h, the low-probability jackpot result, the low winning high-probability jackpot result, and the most advantageous jackpot result are set as the distribution destinations of the jackpot results in the case of the jackpot result.

The low-probability jackpot result is a jackpot result in which the opening/closing execution mode becomes the high-frequency winning mode, and after the opening/closing execution mode ends, the winning/winning lottery mode becomes the low-probability mode and the support mode becomes the high-frequency support mode. However, the high frequency support mode shifts to the low frequency support mode when the number of games reaches the end reference number (specifically, 100 times) after the shift.

The low winning high-accuracy jackpot result is a big hit result in which the opening/closing execution mode becomes the low frequency winning mode, and after the completion of the opening/closing execution mode, the winning/winning lottery mode becomes the high probability mode and the support mode becomes the high frequency support mode. is there. These high-probability mode and high-frequency support mode are continued until the lottery result in the win/loss lottery becomes a big hit state win, and the big hit state due to this is achieved.

The most advantageous jackpot result is a jackpot result in which the opening/closing execution mode becomes the high-frequency winning mode, and after the opening/closing execution mode ends, the win/loss lottery mode becomes the high-probability mode and the support mode becomes the high-frequency support mode. These high-probability mode and high-frequency support mode are continued until the lottery result in the win/loss lottery becomes a big hit state win, and the big hit state due to this is achieved.

The normal game state in relation to each of the above-mentioned game states means not the open/close execution mode but the win/loss lot mode is the low probability mode and the support mode is the low frequency support mode. Further, as a game result, a low winning award high probability jackpot result may not be set. Further, in the opening/closing execution mode in the low winning high-probability jackpot result, the number of round games may be smaller than that in the low-probability jackpot result and the most advantageous jackpot result.

In the distribution table 64h, among the values of the jackpot type counter C2 of "0 to 29", "0 to 9" correspond to the low-probability jackpot result, and "10 to 14" correspond to the low winning high-probability jackpot result. Corresponding, "15-29" corresponds to the most advantageous jackpot results.

Only one kind of distribution table 64h is provided so as to be common in any of the setting states of “setting 1” to “setting 6”. As a result, it is possible to prevent the distribution state of the jackpot result from being advantageous or disadvantageous depending on the setting state of the pachinko machine 10, and a storage capacity for storing the distribution table 64h in the main ROM 64 in advance. Can be suppressed.

The distribution mode of the jackpot results may be different depending on the setting state of the pachinko machine 10. For example, a higher setting value may be configured to increase the probability of being distributed to the most advantageous jackpot result, and a higher setting value may be configured to increase the probability of being distributed to the most advantageous jackpot result or the low winning affirmative jackpot result. In this case, the higher the set value, the higher the probability of becoming the high-probability mode after the jackpot result. In addition, the higher the set value, the lower the probability of being distributed to the high-accuracy jackpot result may be set to be lower. It may be configured so that it can be distributed to the jackpot results. In this case, the higher the set value, the higher the probability that the open/close execution mode of the high frequency winning mode will occur.

Next, the reach random number counter C3 will be described. The reach random number counter C3 is configured to be sequentially incremented by 1 in the range of 0 to 238, for example, and after reaching the maximum value, returns to "0". Expected effects are set in the pachinko machine 10 as a kind of display effects in the symbol display device 41. The expected effect is provided with a symbol display device 41 capable of performing variable display of symbols, and in a game machine in which a final stop result is a given response result in a game time that is a predetermined jackpot result, the symbol display device 41 The display state for making the player think that the variation display state is likely to be the above-mentioned assignment correspondence result in the stage before the stop result is derived and displayed after the variable display of the symbol is started. In addition, as for the assignment correspondence result, specifically, a combination of symbols having the same number is stopped and displayed on any of the activated lines.

Two types of expected display are set: a reach display and a notice display for expecting the occurrence of the reach display or the result of the assignment response in the stage before the reach display occurs.

In the reach display, the symbols are stopped and displayed for a part of the plurality of symbol columns displayed on the display surface 41a of the symbol display device 41, thereby displaying a combination of the reach symbols, and the remaining symbols are displayed in that state. A display state in which a variable display of symbols is performed in the symbol column is included. Also, in the state where the reach symbol combination is displayed as described above, while performing the variable display of the symbols in the remaining symbol columns, the reach effect is displayed by displaying a predetermined character or the like as a moving image on the background screen. , Which includes reducing or displaying a combination of reach patterns and displaying a predetermined character or the like as a moving image on substantially the entire display surface 41a to perform a reach effect.

In the notice display, in a situation where the symbols are variably displayed in all the symbol columns after the variable display of the symbols is started on the display surface 41a of the symbol display device 41, or a part of the symbol columns is plural. In the situation where the symbols are variably displayed in the symbol column, a mode in which the character is displayed separately from the symbols on the symbol column is included. Further, it also includes a background screen having a predetermined mode different from the previous modes and a pattern on the symbol row having a predetermined mode different from the previous modes. Such advance notice display can occur at both game times when the reach display is performed and when the reach display is not performed, but the reach display is higher than the case where the reach display is not performed. It is set to occur with a probability.

The reach display is executed regardless of the value of the reach random number counter C3 in the game time when the same symbol combination is finally stopped and displayed. Moreover, in the game times corresponding to the big hit result in which the same symbol combination is not stopped and displayed, it is not executed regardless of the value of the reach random number counter C3. Further, in the game times corresponding to the deviation result, when the reach random number counter C3 acquired at a predetermined timing by referring to the reach table stored in the main ROM 64 corresponds to the occurrence of the reach display. ..

On the other hand, the decision as to whether or not to display the advance notice is made in the sound emission control device 81, not in the main control device 60. In this case, the sound emission control device 81 is more likely to generate a notice display in the game times corresponding to any of the jackpot results than in the game times corresponding to the miss result, and displays a notice display with a low appearance rate. The lottery process for displaying the advance notice is executed so as to satisfy at least one of the conditions that is likely to occur. By the way, this lottery result is reflected when the effect for game use is executed on the symbol display device 41.

Here, the probability that the reach display is generated in the game times that result in the deviation is the same in any of the setting states of "setting 1" to "setting 6". As a result, it is possible to prevent an advantage or a disadvantage due to the setting state of the pachinko machine 10 from occurring with respect to the probability that the reach display is generated in the game times that result in the deviation. However, the present invention is not limited to this, and the higher the set value, the higher the probability that the reach display will occur in the game times that result in the deviation.

Next, the fluctuation type counter CS will be described. The fluctuation type counter CS is configured to be incremented by 1 in the range of 0 to 198, for example, and return to "0" after reaching the maximum value. The fluctuation type counter CS is used when the main CPU 63 determines the display duration time in the special figure display portion 37a and the display duration time of the symbol in the symbol display device 41. The variation type counter CS is updated once every time a timer interrupt process described later is executed, and is repeatedly updated within the remaining time until the next timer interrupt process is executed. Then, the buffer value of the fluctuation type counter CS is acquired when the fluctuation display is determined on the special figure display unit 37a and when the fluctuation display of the symbol by the symbol display device 41 is started.

<Regarding the processing configuration of the main CPU 63>
Next, each process executed by the main CPU 63 for advancing a game will be described. The processes of the main CPU 63 are roughly classified into a main process that is started when the power is turned on and a timer interrupt process that is started periodically (in this embodiment, at a cycle of 4 milliseconds).

<Main processing>
First, the main process will be described with reference to the flowchart of FIG.

First, power-on wait processing is executed (step S101). In the power-on wait process, for example, the main process is started and waits for a predetermined time for waiting (specifically, 1 second) without proceeding to the next process. During the execution period of the power-on weight process, the operation start and initial setting of the symbol display device 41 are completed. After that, access to the main RAM 65 is permitted (step S102).

Then, it is determined whether or not the setting key insertion portion 68a has been turned on (step S103). When the setting key insertion portion 68a has not been turned on (step S103: NO), it is determined whether the reset button 68c has been pressed (step S104). When the reset button 68c is pressed (step S104: YES), each area of the main RAM 65 is set to "except for the area in the main RAM 65 in which the information of the setting value indicating the setting state of the pachinko machine 10 is set. When "0" is cleared, initial setting is performed for the area where "0" is cleared (step S105). In other words, when the supply of operating power to the pachinko machine 10 is started while pressing the reset button 68c without turning on the setting key insertion portion 68a, the operation of the pachinko machine 10 for setting value information is started. The clear process of the main RAM 65 is executed while maintaining the state before the power supply is stopped, and the storage area where the clear process is executed is initialized. As a result, other areas of the main RAM 65 can be initialized without changing the set value. In step S105, various registers of the main CPU 63 are cleared to "0" and then initialized.

When the reset button 68c has not been pressed (step S104: NO), it is determined whether the power failure flag is set to "1" (step S106). The power failure flag is provided in the main RAM 65, and when the power failure supply to the main CPU 63 is stopped and a predetermined power failure process is normally executed, the power failure flag is set to "1". Will be set. When the power failure flag is set to "1", it is determined whether the checksum calculation result matches the checksum saved when the power is cut off, that is, the validity of the stored data is determined (step S107). .. When the process of step S105 is executed, or when the positive determination is made in step S107, it is determined whether the set value of the pachinko machine 10 is normal by checking the main RAM 65 (step S108). Specifically, it is determined to be normal when the setting value is any of "setting 1" to "setting 6", and abnormal when it is "0" or 7 or more.

When a negative determination is made in any of steps S106 to S108, the operation prohibition process is executed. In the operation prohibition process, an infinite loop is performed after the error notification process for notifying the hall manager or the like of the occurrence of an error (step S109). The operation prohibition process is canceled by executing the all clear process (step S117) described later.

When a positive determination is made in all of steps S106 to S108, power-on setting processing is executed (step S110). In the power-on setting process, a predetermined area of the main RAM 65 such as initialization of a power failure flag is set to an initial value, and a command corresponding to the current game state is transmitted to the voice emission control device 81. After executing the process of step S110, the management IC 66 recognizes various information (step S111) and outputs various data to an external device connected to the reading terminal 68d of the MPU 62. A data output process is executed (step S112). Details of these recognition processing and data output processing will be described later.

Although the main CPU 63 is configured to periodically execute the timer interrupt process, the generation of the timer interrupt process is prohibited when the main process is started. The state in which the generation of the timer interrupt process is prohibited is released at the timing before the process of step S112 is completed and the process of step S113 is executed, and the execution of the timer interrupt process is permitted. As a result, when the supply of the operating power to the main CPU 63 is started, the data output process of step S112 ends, and the timer interrupt process is not executed until the stage before the process of step S113 is started. Therefore, the processing for advancing the game in the main CPU 63 is not started until this situation is reached.

After that, the process proceeds to the residual process of steps S113 to S116. That is, the main CPU 63 is configured to periodically execute the timer interrupt process, but a residual time is generated between one timer interrupt process and the next timer interrupt process. This remaining time will vary depending on the processing completion time of each timer interrupt processing, but the remaining processing of steps S113 to S116 is repeatedly executed using this irregular time. In this respect, it can be said that the residual process of steps S113 to S116 is an irregular process that is irregularly executed.

In the residual processing, first, in step S113, interrupt prohibition is set in order to prohibit the occurrence of timer interrupt processing. In a succeeding step S114, a random number initial value updating process for updating the random number initial value counter CINI is executed, and at the same time, a fluctuation counter updating process for updating the fluctuation type counter CS is executed in step S115. In these updating processes, the current numerical value information is read from the corresponding counter of the main RAM 65, the process of adding 1 to the read numerical value information is performed, and then the process of overwriting the counter of the reading source is executed. In this case, when the counter value exceeds the maximum value, each is cleared to "0". After that, in step S116, an interrupt permission setting for switching from the state in which the generation of the timer interrupt process is prohibited to the state in which the timer interrupt processing is permitted is set. When the process of step S116 is executed, the process returns to step S113, and the processes of steps S113 to S116 are repeated.

On the other hand, when the setting key insertion portion 68a is turned on (step S103: YES), the main RAM 65 including the area in which the setting value information indicating the setting state of the pachinko machine 10 is set. All the areas are cleared to "0" and the areas cleared to "0" are initialized (step S117). That is, when an operation for changing the setting state of the pachinko machine 10 is performed, all areas of the main RAM 65 are cleared to "0" and cleared even if the reset button 68c is not pressed. Initial setting is performed for the storage area in which the processing is executed. Further, in step S117, various registers of the main CPU 63 are also cleared to "0" and then initialized. However, the present invention is not limited to this, and even when an operation for changing the setting state of the pachinko machine 10 is performed, if the reset button 68c is not pressed, the entire RAM 65 on the main side is not operated. The clearing process may be executed without performing the clearing process and when the operation for changing the setting state of the pachinko machine 10 is performed and the reset button 68c is pressed.

After that, the set value update processing is executed in step S118, the set value update signal output processing is executed in step S119, and then the process proceeds to step S110. The setting value update process will be described below. The output process of the set value update signal will be described later in detail. FIG. 10 is a flowchart showing the set value updating process.

First, "1" is set in the set value counter provided in the main RAM 65 (step S201). The set value counter is a counter for the main CPU 63 to specify which set value the set state of the pachinko machine 10 is. By setting "1" in the set value counter, when the set value updating process is executed, the set value becomes "set 1" regardless of the set value up to that point.

Then, the display start processing of the set value is executed (step S202). In the setting value display start processing, the display of the third notification display device 69c is controlled so that the number "1" corresponding to "Setting 1" is displayed. When changing the set value, the manager of the game hall can confirm the current setting state of the pachinko machine 10 by checking the third notification display device 69c.

Then, it is determined whether the update button 68b has been pressed once (step S204) on condition that the setting key insertion part 68a has not been operated OFF (step S203: NO). Specifically, it is determined whether or not the signal from the sensor that detects the pressing operation of the update button 68b has switched from the LOW level to the HI level. When a negative determination is made in step S204, the process returns to step S203, and it is determined whether or not the setting key insertion portion 68a has been turned off.

When the update button 68b is pressed once (step S204: YES), the value of the set value counter of the main RAM 65 is incremented by 1 (step S205). When the value of the set value counter after adding 1 exceeds "6" (step S206: YES), "1" is set in the set value counter (step S207). As a result, each time the update button 68b is pressed once, it is updated to the set value one step higher, and when the update button 68b is pressed once in the situation of "setting 6", it is set to "setting 1". Will return.

When a negative determination is made in step S206 or when the process of step S207 is executed, the display update process of the set value is executed (step S208). In the display update process of the set value, the display of the third notification display device 69c is controlled so that the number corresponding to the value of the set value counter of the main RAM 65 is displayed. By checking the third notification display device 69c, the manager of the game hall can grasp the setting state of the pachinko machine 10 after pressing the update button 68b.

After executing the process of step S208, the process returns to step S203, and it is determined whether or not the setting key insertion unit 68a has been turned off. When the OFF operation has not been performed (step S203: NO), the processes of step S204 and thereafter are executed again. If the OFF operation has been performed (step S203: YES), display end processing of the set value is executed (step S209). In the display end processing of the set value, the display of the set value on the third notification display device 69c is ended.

<Timer interrupt processing>
Next, the timer interrupt processing will be described with reference to the flowchart of FIG. The timer interrupt processing is executed periodically (for example, every 4 milliseconds).

First, a power failure information storage process is executed (step S301). In the power failure information storage processing, it is monitored whether or not a power failure signal corresponding to the occurrence of the power cutoff is received from the power failure monitoring board 67, and when the occurrence of the power failure is identified, the power failure processing is executed and an infinite loop is executed. Become. In the power failure process, the power failure flag of the main RAM 65 is set to "1", the checksum is calculated, and the calculated checksum is saved.

After that, random number update processing for lottery is executed (step S302). In the lottery random number updating process, the winning random number counter C1, the big hit type counter C2, the reach random number counter C3, and the general electric utility article release counter C4 are updated. Specifically, the current numerical value information is sequentially read from the winning random number counter C1, the jackpot type counter C2, the reach random number counter C3, and the general electric utility open counter C4, and the processing of adding 1 to each of the read numerical value information is executed. After that, a process of overwriting the counter of the reading source is executed. In this case, when the counter value exceeds the maximum value, each is cleared to "0". After that, in step S303, the random number initial value updating process is executed as in step S114, and at the same time, the fluctuation counter updating process is executed in step S304 as in step S115.

After that, the fraud detection process of monitoring whether or not a predetermined event set as a fraudulent monitoring target has occurred is executed (step S305). In the fraud detection process, the occurrence of a plurality of types of events is monitored, and by confirming that a predetermined event has occurred, "1" is set in the game stop flag provided in the main RAM 65. In a succeeding step S306, it is determined whether or not the progress of the game is stopped by determining whether or not the game stop flag is set to "1". When a negative determination is made in step S306, the processing from step S307 is executed.

In step S307, port output processing is executed. In the port output process, when the output information has been set in the previous timer interrupt process, a process for outputting to the various driving units 32b and 34b corresponding to the output information is executed. For example, when the information to switch the special electric prize winning device 32 to the open state is set, the output of the drive signal to the special electric drive unit 32b is started, and the information to switch to the closed state is set. Stops the output of the drive signal. Further, when the information for switching the universal electric accessory 34a of the second operation port 34 to the open state is set, the output of the drive signal to the drive unit 34b for the general electric power is started to switch to the closed state. When the information is set, the output of the drive signal is stopped.

Then, the reading process is executed (step S308). In the reading process, signals other than the power failure signal and the winning signal are read, and the read information is stored for use in future processes.

After that, a ball detection process is executed (step S309). In the entrance detection process, the signals received from the entrance detection sensors 42a to 49a are read, and based on the read results, the outlet 24a, the general winning opening 31, the special prize winning device 32, and the first operating opening 33. The presence or absence of a ball entering the second operating port 34 and the through gate 35 is specified. The details of the incoming ball detection process will be described later.

After that, a timer updating process for collectively updating the numerical information of a plurality of types of timer counters provided in the main RAM 65 is executed (step S310). In this case, the configuration is such that the timer counters that are updated by subtracting the stored numerical value information are aggregated and handled, but both the subtraction timer counter update and the addition timer counter update are aggregated and performed. It may be configured.

After that, a firing control process for controlling the firing of the game ball is executed (step S311). In the situation where the firing operation to the firing operation device 28 is continued, one game ball is fired in a predetermined firing cycle of 0.6 seconds. In subsequent step S312, as input state monitoring processing, based on the information read in the reading processing in step S308, disconnection confirmation of each of the ball detection sensors 42a to 49a and open confirmation of the gaming machine main body 12 and the front door frame 14 are performed. I do.

After that, the special figure special electric power control processing for executing the execution control of the game times and the execution control of the opening/closing execution mode is executed (step S313). The special figure special electric power control processing will be described in detail later.

After that, the universal figure/universal control process is executed (step S314). In the general/universal/universal control process, a process for acquiring the general/universal-university-side pending information is executed when a prize is paid to the through gate 35, and the general-universal/universal-side pending information is stored. Then, the release information is determined to be released, and the processing for performing the effect for the universal figure is executed when the release determination is triggered. In addition, based on the result of the open determination, a process of opening and closing the universal electric accessory 34a of the second operating port 34 is executed. In this case, if the support mode is the low frequency support mode, the corresponding process is executed, and if the support mode is the high frequency support mode, the corresponding process is executed. Further, in the case of the open/close execution mode, even if the support mode immediately before that is the high frequency support mode, it becomes the low frequency support mode.

In the following step S315, based on the processing results of the immediately preceding steps S313 and S314, the output information for reflecting the increased/decreased number of the hold information related to the special figure display unit 37a in the special figure hold display unit 37b is set and The output information for reflecting the increased/decreased number of the hold information related to the universal figure display section 38a on the universal figure hold display section 38b is set. In step S315, the output information for updating the display content of the special figure display portion 37a is set based on the processing results of the immediately preceding steps S313 and S314, and the display content of the general figure display portion 38a is set. Set the output information for updating.

After that, the contents of the command and the signal received from the payout control device 77 are confirmed, and the payout state receiving process for performing the process corresponding to the confirmation result is executed (step S316). Further, a payout output process for setting the prize ball command as an output target is executed (step S317). Further, the external information setting process for controlling the start and end of the output of the external signal according to the processing result of the various processes executed in the timer interrupt process this time is executed (step S318). Then, the management output process for outputting the information corresponding to the result of entering the game ball in the game area PA to the management IC 66 is executed (step S319). Details of the management output process will be described later.

Next, the special figure special electric power control processing in step S313 will be described with reference to the flowchart in FIG.

First, a process of acquiring pending information is executed (step S401). In the process of acquiring the hold information, it is determined whether or not a prize has been paid to the first working opening 33 or the second working opening 34, and if a winning has occurred, the number of holdings in the holding storage area 65a is the upper limit. It is determined whether it is less than the value (“4” in the present embodiment). If the number of reservations is less than the upper limit value, the number of reservations is incremented by 1, and each numerical value information of the hit random number counter C1, the big hit type counter C2, and the reach random number counter C3 updated in the previous step S302 is used for holding. It is stored in the first holding area among the empty holding areas RE1 to RE4 of the area RE. In addition, when the winning to the first working opening 33 and the second working opening 34 occurs at the same time, the processing for obtaining the holding information is performed within the range in which the holding information obtaining processing is executed once. Run multiple times. Further, when a new acquisition of the hold information is performed, a corresponding acquisition-time command is transmitted to the voice emission control device 81. When the voice emission control device 81 receives the command, it updates the display of the image showing the number of the hold information on the symbol display device 41 to the display content corresponding to the increase of the hold information.

After that, the information of the special figure special power counter provided in the main RAM 65 is read (step S402), and the special figure special power address table provided in the main ROM 64 is read (step S403). Then, the start address corresponding to the information of the special map special telephone address is acquired from the special figure special telephone address table (step S404), and the process jumps to the process indicated by the obtained start address among the processes of steps S406 to S412 (step S405). ). The special figure special telephone counter is a counter for the main CPU 63 to know which of the various processes of steps S406 to S412 should be executed, and the special figure special telephone address table is The start address of the program for executing the processes of steps S406 to S412 is set in association with the numerical information.

In step S406, special figure variation start processing is executed. FIG. 13 is a flowchart showing the special figure variation start processing.

In the special figure variation start processing, the data setting processing is executed (step S502) on condition that the number of pieces of holding information stored in the holding area RE is 1 or more (step S501: YES). In the data setting process, first, the number of holdings is decremented by 1, and the data stored in the first holding area RE1 of the holding area RE is moved to the execution area AE. Then, the process of shifting the data stored in each of the holding areas RE1 to RE4 of the holding area RE is executed. This data shift process is a process of sequentially shifting the data stored in the first holding area RE1 to the fourth holding area RE4 to the lower area side, and specifically, the second holding area RE2→the first holding area RE1. , The third reservation area RE3→the second reservation area RE2, the fourth reservation area RE4→the third reservation area RE3, and the like, and then the fourth reservation area RE4 is cleared to “0”. At this time, a shift command for recognizing that the data in the holding area has been shifted is transmitted to the voice emission control device 81. When the voice emission control device 81 receives the command, it updates the display of the image showing the number of the hold information on the symbol display device 41 to the display content corresponding to the decrease of the hold information.

After executing the data setting process, the win/loss table is read from the main ROM 64 (step S503). Specifically, first, the information indicating the win/loss lottery mode of the main RAM 65 is read to grasp the current win/loss lottery mode. In the case of the high probability mode, the high probability table 64g is read from the main ROM 64. On the other hand, in the low probability mode, the setting state of the pachinko machine 10 is grasped by reading the value of the setting value counter of the main RAM 65. Then, the low-probability table 64a to 64f corresponding to the grasped setting value is read from the main ROM 64.

After that, the win/loss determination process is executed by referring to the win/loss tables 64a to 64g read in step S503 (step S504). In the hit determination processing, the information for hit determination of the information stored in the execution area AE, that is, the numerical value information related to the hit random number counter C1 is the jackpot numerical value information set in the hit/miss tables 64a to 64g read in step S503. It is determined whether or not

When the result of the win/loss determination process is the jackpot win result (step S505: YES), the distribution determination process is executed (step S506). In the distribution determination process, the information for distribution determination, that is, the numerical information related to the jackpot type counter C2 is read out from the information stored in the execution area AE. Then, by referring to the distribution table 64h provided in the main ROM 64, it is specified which jackpot result the numerical information relating to the read jackpot type counter C2 corresponds to. Specifically, it specifies which of the low-probability jackpot result, the low winning high-probability jackpot result, and the most advantageous jackpot result corresponds to the jackpot result.

After that, the stop result setting process for the jackpot result is executed (step S507). Specifically, in the game time related to the start of the variation this time, information about the mode of the pattern to be finally stopped and displayed on the special figure display unit 37a is stored in the main ROM 64 in advance in the stop result table for the jackpot result. It is specified, and the specified information is written in the main RAM 65. In this big hit result stop result table, information on the form of the pattern stopped and displayed on the special figure display portion 37a is set differently for each kind of big hit result.

Then, a flag setting process corresponding to the distribution determination result is executed (step S508). Specifically, the main RAM 65 is provided with a flag corresponding to each kind of jackpot result, and in step S508, among the flags corresponding to each kind of jackpot result, of the distribution determination processing of step S506. "1" is set to the flag corresponding to the result.

On the other hand, when it is determined in step S505 that the result is not the jackpot, the stop result setting process for the result of deviation is executed (step S509). Specifically, in the game time relating to the start of the variation this time, information about the mode of the design to be finally stopped and displayed on the special figure display portion 37a is stored in the main side ROM 64 in advance from the stop result table for the disconnection result. It is specified, and the specified information is written in the main RAM 65. The information on the pattern mode selected in this case is different from the information on the pattern mode selected in the case of the jackpot result.

After performing the process of either step S508 or step S509, the process of grasping the duration of the game is performed (step S510). In this processing, the numerical information of the fluctuation type counter CS is acquired. Further, it is determined whether or not the reach display is generated on the symbol display device 41 in the current game time. Specifically, when the game time related to the current fluctuation start is the low-probability jackpot result or the most advantageous jackpot result, it is determined that the reach display is generated. Further, if it is not any jackpot result and the numerical value information regarding the reach random number counter C3 stored in the execution area AE is the numerical information corresponding to the occurrence of the reach, it is determined that the reach display is generated.

When it is determined that the reach display occurs, the reach generation continuation period table stored in the main ROM 64 is referred to, and the continuation period of the game time corresponding to the numerical value information of the current variation type counter CS is acquired. .. On the other hand, when it is determined that the reach display does not occur, the continuation of the game times corresponding to the numerical value information of the variation type counter CS of this time is referred to by referring to the reach non-occurrence duration table stored in the main ROM 64. Get the period. By the way, the duration of game times that can be obtained by referring to the reach non-occurrence duration table is different from the duration of game times that can be obtained by referring to the reach non-occurrence duration table.

The duration of the game times when the reach is not generated is set so that the duration of the game times becomes shorter as the number of pieces of holding information stored in the holding area RE increases. Also, in the situation where the support mode is the high frequency support mode, compared to the situation where the support information is in the low frequency support mode, the duration of the shorter game times is selected in comparison with the case where the number of pieces of holding information is the same. A reach non-occurrence duration table is set. However, the present invention is not limited to this, and the duration of the game times may not change according to the number of pieces of hold information and the support mode, and the above relationship may be reversed. Furthermore, the above configuration may be applied to the duration of the game times when the reach occurs. Further, the duration table may be set individually for each of the various jackpot results, the case of the missed reach, and the case of the missed result of the non-reach occurrence. In this case, the duration of the game times is distributed according to each game result.

After that, the information on the duration of the game times acquired in step S510 is set in the special figure special power timer counter provided in the main side RAM 65 (step S511). The updating of the numerical information set in the special figure special electric timer counter is executed in the timer updating process (step S310). By the way, as the effect for game play, the variable display of the symbol on the special figure display portion 37a and the variable display of the symbol on the symbol display device 41 are performed. In the state in which the stop result is displayed (a state in which a predetermined symbol combination is waiting on the activated line in the symbol display device 41), the final stop is displayed for the final stop period (for example, 0.5 seconds). In this case, the duration of the game time acquired in step S510 is the total time for one game time.

After that, the variation command and the type command are transmitted to the voice emission control device 81 (step S512). The variation command includes information on the duration of the game. Here, as described above, the duration of the game times obtained by referring to the reach non-occurrence duration table is different from the duration of the game times obtained by referring to the reach occurrence duration table. Even if the variation command does not include the information regarding the presence or absence of the reach occurrence, the voice emission control device 81 can identify the presence or absence of the reach occurrence from the information on the duration of the game. In this respect, it can be said that the variation command includes information indicating whether or not reach has occurred. It should be noted that the variation command may include information that directly indicates whether or not the reach has occurred. Further, the type command includes information on the game result.

When the voice emission control device 81 receives the variation command and the type command from the main CPU 63, the display light emission part 53, the speaker part 54, and the symbol display device 41 are caused to execute the game reproduction effect. In this case, the effect for game play is performed in a mode corresponding to the contents of the variation command and the type command. Further, in the symbol display device 41, variable display of symbols is performed as an effect for game use, and when the effect for game use is finished, a combination of symbols corresponding to the result of the win/loss determination process and the distribution determination process is displayed. It will be stopped.

After that, the variable display of the pattern on the special figure display portion 37a is started (step S513). Then, the special figure special power counter is incremented by 1 (step S514). In this case, the numerical information of the special figure special electric counter is "0" when the special figure fluctuation start process is executed, and thus the numerical information of the special figure special electric counter is "1". After that, "1" is set to the eleventh output flag provided in the main RAM 65 (step S515). The eleventh output flag is a flag for the main CPU 63 to specify that the information output indicating that the game time has started is to be executed to the management IC 66.

Returning to the explanation of the special figure special power control process (FIG. 52 ), the special figure changing process is executed in step S407. In the special figure changing process, it is determined whether or not it is the timing before the final stop display during the duration of the game time. Process for changing the target. At the time of the final stop display, by adding 1 to the numerical information of the special map special electric counter, the numerical information of the counter corresponds to the special figure changing process from the special figure changing process. Update to stuff. In this embodiment, the final stop command is not transmitted from the main CPU 63 to the sound emission control device 81.

In step S408, the processing for determining the special figure is executed. In the special figure finalizing process, the display mode of the pattern on the special figure display portion 37a is set to the display mode corresponding to the lottery result of the current game. In addition, in the special figure finalization process, it is determined whether or not the final stop period has elapsed, and if the period has elapsed, it is determined whether or not the transition to the open/close execution mode occurs. When the switching to the open/close execution mode does not occur, the numerical information of the special figure special power counter is cleared to "0". When the shift to the open/close execution mode occurs, the numerical information of the special map special electric counter is incremented by 1 to change the numerical information of the counter from the one corresponding to the special figure fixing process to the special electric start process. Update.

In step S409, special electric power start processing is executed. In the special electric power start process, if the process for starting the opening period in the current open/close execution mode has not been executed yet, the opening period setting process is executed. Further, the opening command is transmitted to the voice emission control device 81. Upon receiving the opening command, the voice emission control device 81 causes the display light emitting unit 53, the speaker unit 54, and the symbol display device 41 to execute the opening effect. When the opening period has elapsed, the starting process for starting the first round game is executed. In the starting process, the special electric prize winning device 32 is opened and the ending condition of the round game is set. In setting the ending condition, the upper limit duration for setting the special electric prize winning device 32 to be kept open in the first round game of this time is set, and the special electric prize device 32 can be won in the first round game of this time. The upper limit number of game balls is set in the winning number counter provided in the main RAM 65.

In step S410, the special electric power releasing processing is executed. In the special electric current open process, it is determined whether or not the condition for ending the round game is satisfied. When the ending condition is satisfied, the special electric prize winning device 32 is closed. Then, if the round game that has ended this time is not the last round game of the execution time, the numerical information of the special map special electric counter is incremented by 1 to change the numerical information of the counter from the special electric open processing to the special electric closing processing. If the round game ended this time is the round game of the last execution time, the numerical information of the special map special electric counter is added by 2 to correspond to the special electric open processing. Update from the one that corresponds to the special telephone end processing.

In step S411, a special electric power closing process is executed. In the special electric closed processing, it is determined whether or not the interval period between round games has passed. The interval period is set when the previous round game ends. When the interval period has elapsed, the special electric winning device 32 is opened and the ending condition of the round game is set. Then, by subtracting 1 from the numerical information of the special figure special electric power counter, the numerical information of the counter is updated from the value corresponding to the special electric power closing processing to the value corresponding to the special electric open processing.

In step S412, special electric power termination processing is executed. In the special power termination process, if the process for starting the ending period in the opening/closing execution mode this time has not been executed yet, the ending period (for example, 5 seconds) is set and the ending command is transmitted to the sound emission control device 81. .. By receiving the ending command, the voice emission control device 81 causes the display light emitting unit 53, the speaker unit 54, and the symbol display device 41 to execute the ending effect. When the ending period has elapsed, each of the winning/losing lottery mode and the support mode after the end of the opening/closing execution mode is set to the mode corresponding to the jackpot result which triggered the opening/closing execution mode of this time.

Next, in the main CPU 63, based on the detection results of the respective ball detection sensors 42a to 49a, the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first working opening 33, the second working opening 34, and the through. A configuration for specifying whether or not a game ball enters the gate 35 will be described. FIG. 14 is an explanatory diagram for explaining a configuration in which the detection results of the ball entrance detection sensors 42a to 49a are input to the main CPU 63.

The main CPU 63 is provided with an input port 63a. The input port 63a is configured as an 8-bit parallel interface so that it can simultaneously handle eight types of signals. Areas in which information of "0" or "1" is stored according to the voltage of each signal are provided in a one-to-one correspondence with each terminal. That is, the 0th bit D0 to the 7th bit D7 are provided as the area. Further, although more than eight kinds of signals are input to the input port 63a, the signal group to be input to the input port 63a depends on the driver IC in order to limit the simultaneous input to eight kinds. It can be switched through the switching control.

In the incoming ball detection process (step S309) of the timer interrupt process (FIG. 11), the signal group to be input to the input port 63a is set to the signal group from each of the incoming ball detection sensors 42a to 49a. In the situation where such a setting is made, the 0th bit D0 stores information corresponding to the detection signal from the first winning opening detection sensor 42a, and the first bit D1 corresponds to the detection signal from the second winning opening detection sensor 43a. The information corresponding to the detection signal from the third winning a prize detection sensor 44a is stored in the second bit D2, and the information corresponding to the detection signal from the special electric power detection sensor 45a is stored in the third bit D3. , The fourth bit D4 stores information corresponding to the detection signal from the first working port detection sensor 46a, and the fifth bit D5 stores information corresponding to the detection signal from the second working port detection sensor 47a. The 6-bit D6 stores information corresponding to the detection signal from the outlet detection sensor 48a, and the 7th bit D7 stores information corresponding to the detection signal from the gate detection sensor 49a.

When the passage of the game ball is not detected, each of the ball detection sensors 42a to 49a outputs a LOW level signal indicating that the game ball is not being detected, and detects the passage of the game ball. In that case, a HI level signal indicating that the detection is being performed is output as the detection signal. The input port 63a stores "0" information for the corresponding bit when receiving the LOW level signal, and "1" for the corresponding bit when receiving the HI level signal. Stores the information of. That is, in the situation where passage of the game ball is not detected by the ball detection sensors 42a to 49a, information of "0" corresponding to the information indicating non-detection is stored for the corresponding bit, and the passage of the game ball is detected. In the detected state, information of "1" corresponding to the information indicating that the bit is being detected is stored for the corresponding bit.

FIG. 15 is a flow chart showing the incoming ball detection process executed in step S309 of the timer interrupt process (FIG. 11).

When it is confirmed that the state in which the information of “0” is stored in the 0th bit D0 is changed to the state in which the information of “1” is stored, one piece is detected by the first winning opening detection sensor 42a. It is determined that a game ball has been detected (step S601: YES). In this case, "1" is set to the first output flag provided in the main RAM 65 (step S602), and the value of the 10 award ball counter provided in the main RAM 65 is incremented by 1 (step S603). .. The first output flag is used by the main CPU 63 to specify that the information output indicating that one gaming ball has been detected by the first winning opening detection sensor 42a should be executed for the management IC 66. It is a flag. The ten prize ball counter is a counter for the main CPU 63 to specify the number of times that the payout of ten game balls should be executed. When the value of the counter for 10 award balls is 1 or more, the 10 award ball command is output to the award controller 77 in the payout output process of step S317 in the timer interrupt process (FIG. 11), and the 10 award balls are issued. When the command is output once, the value of the counter for 10 prize balls is decremented by 1. When the payout control device 77 receives the 10 prize ball command, it drives and controls the payout device 76 so that 10 game balls are paid out.

When it is confirmed that the situation in which the information of "0" is stored in the first bit D1 is switched to the situation in which the information of "1" is stored, one piece is detected by the second winning opening detection sensor 43a. It is determined that a game ball has been detected (step S604: YES). In this case, "1" is set to the second output flag provided in the main RAM 65 (step S605), and the value of the 10 award ball counter provided in the main RAM 65 is incremented by 1 (step S606). .. The second output flag is used for the main CPU 63 to specify that the information output indicating that one gaming ball has been detected by the second winning hole detection sensor 43a should be executed for the management IC 66. It is a flag.

When it is confirmed that the situation in which the information of "0" is stored in the second bit D2 is switched to the situation in which the information of "1" is stored, one piece is detected by the third winning opening detection sensor 44a. It is determined that a game ball has been detected (step S607: YES). In this case, "1" is set to the third output flag provided in the main RAM 65 (step S608), and the value of the 10 award ball counter provided in the main RAM 65 is incremented by 1 (step S609). .. The third output flag is used by the main CPU 63 to specify that the information output indicating that one gaming ball has been detected by the third winning opening detection sensor 44a should be executed for the management IC 66. It is a flag.

When it is confirmed that the situation in which the information of "0" is stored in the third bit D3 is switched to the situation in which the information of "1" is stored, one game ball is detected by the special-electricity detection sensor 45a. It is determined that it has been detected (step S610: YES). In this case, the special electricity prize flag provided in the main RAM 65 is set to "1" (step S611), and the fourth output flag provided to the main RAM 65 is set to "1" (step S612). The value of the counter for 15 prize balls provided in the main RAM 65 is incremented by 1 (step S613). The special electric prize flag is a flag for the main CPU 63 to specify that one game ball has entered the special electric prize device 32 in the round game in the opening/closing execution mode. In the special figure special electric power control processing (step S313) of the timer interruption processing (FIG. 11), by confirming that the special electric prize winning flag is set to "1", one game ball is inserted into the special electric prize winning device 32. It is specified that a ball has occurred, and the remaining possible number of balls to enter the special electric prize winning device 32 in the round game is subtracted by one. When the process of subtracting 1 from the number of possible balls to enter is executed, the special electric prize flag is cleared to "0". The fourth output flag is a flag for the main CPU 63 to specify that the information output indicating that one game ball is detected by the special electric power detection sensor 45a should be executed to the management IC 66. .. The counter for 15 prize balls is a counter for the main CPU 63 to specify the number of times the payout of 15 game balls should be executed. When the value of the counter for 15 prize balls is 1 or more, the 15 prize ball command is output to the payout control device 77 in the payout output process of step S317 in the timer interrupt process (FIG. 11), and the 15 prize balls are also displayed. When the command is output once, the value of the counter for 15 prize balls is decremented by 1. When the payout control device 77 receives the 15 prize ball command, it drives and controls the payout device 76 so that 15 game balls are paid out.

When it is confirmed that the state in which the information of “0” is stored in the fourth bit D4 is switched to the state in which the information of “1” is stored, the first operating port detection sensor 46a detects one It is determined that a game ball has been detected (step S614: YES). In this case, the first operation winning flag provided in the main RAM 65 is set to "1" (step S615), and the fifth output flag provided to the main RAM 65 is set to "1" (step S616). Further, the value of the one prize ball counter provided in the main RAM 65 is incremented by 1 (step S617). The first operation winning flag is a flag for the main CPU 63 to specify that one game ball has entered the first operation opening 33. In the special figure special electric power control process (step S313) of the timer interrupt process (FIG. 11), it is confirmed that the first operation winning flag is set to “1”, and thus the result is stored in the holding area RE of the holding storage area 65a. On condition that the number of held information items is less than 4, which is the upper limit number, a process of newly storing the held information items is executed. In the special electric special electric power control processing (step S313), it is confirmed that the first operation winning flag is set to "1", and when the processing corresponding to the confirmation is executed, the first operation winning flag is cleared to "0". To do. The fifth output flag is used for the main CPU 63 to specify that the information output indicating that one gaming ball has been detected by the first working opening detection sensor 46a should be executed for the management IC 66. It is a flag. The one prize ball counter is a counter for the main CPU 63 to specify the number of times that one gaming ball should be paid out. When the value of the one prize ball counter is 1 or more, the one prize ball command is output to the payout control device 77 in the payout output process of step S317 in the timer interrupt process (FIG. 11), and the one prize ball is obtained. When the command is output once, the value of the one prize ball counter is decremented by one. When the payout control device 77 receives the one prize ball command, it drives and controls the payout device 76 so that one game ball is paid out.

When it is confirmed that the state in which the information of “0” is stored in the fifth bit D5 is switched to the state in which the information of “1” is stored, the second working port detection sensor 47a detects one It is determined that a game ball has been detected (step S618: YES). In this case, "1" is set to the second operation winning flag provided in the main RAM 65 (step S619), and "1" is set to the sixth output flag provided in the main RAM 65 (step S620). Further, the value of the one prize ball counter provided in the main RAM 65 is incremented by 1 (step S621). The second operation winning flag is a flag for the main CPU 63 to specify that one game ball has entered the second operating port 34. In the special figure special electric power control process (step S313) of the timer interrupt process (FIG. 11), it is confirmed that the second operation winning flag is set to “1”, and the result is stored in the holding area RE of the holding storage area 65a. On condition that the number of held information items is less than 4, which is the upper limit number, a process of newly storing the held information items is executed. In the special electric special electric power control processing (step S313), it is confirmed that the second operation winning flag is set to "1", and when the processing corresponding to the confirmation is executed, the second operation winning flag is cleared to "0". To do. The sixth output flag is used for the main CPU 63 to specify that the information output indicating that one gaming ball has been detected by the second working opening detection sensor 47a should be executed for the management IC 66. It is a flag.

When it is confirmed that the state in which the information of "0" is stored in the sixth bit D6 is switched to the state in which the information of "1" is stored, one game ball is detected by the out-mouth detection sensor 48a. Is detected (step S622: YES). In this case, the seventh output flag provided in the main RAM 65 is set to "1" (step S623). The seventh output flag is a flag for the main CPU 63 to specify that the information output indicating that one gaming ball has been detected by the outlet detection sensor 48a should be executed for the management IC 66. is there.

When it is confirmed that the situation where the information of "0" is stored in the seventh bit D7 is switched to the situation where the information of "1" is stored, one game ball is detected by the gate detection sensor 49a. It is determined that it has been detected (step S624: YES). In this case, the gate winning flag provided in the main RAM 65 is set to "1" (step S625). The gate winning flag is a flag for the main CPU 63 to specify that one game ball has entered the through gate 35. In the universal communication control processing (step S314) of the timer interrupt processing (FIG. 11), it is confirmed that the gate winning flag is set to "1", and the universal communication stored in the universal communication holding area 65c is confirmed. A process of storing the numerical information of the current universal electric accessory release counter C4 in the general electric power holding area 65c as the general-use-side holding information, provided that the number of pieces of the holding information on the side is less than the upper limit of four pieces. To execute. It is confirmed that the gate winning flag is set to "1" in the universal figure control process (step S314), and when the process corresponding to the confirmation is executed, the gate winning flag is cleared to "0".

Since the timer interrupt process (FIG. 11) is activated in a cycle of 4 milliseconds as already described, if the detection of one game ball is started by one of the entrance detection sensors 42a to 49a, The main CPU 63 identifies the fact that one game ball is detected by the ball detection sensors 42a to 49a in a situation where the one ball is detected by the ball detection sensors 42a to 49a. Will be held in. Therefore, it suffices if each one of the first to seventh output flags is provided.

Next, the content of processing executed by the payout control device 77 will be described. First, the electrical configuration of the payout control device 77 and various devices that communicate with the payout control device 77 will be described with reference to the block diagram of FIG. 16.

The payout control device 77 includes an MPU 91. The MPU 91 includes a payout side CPU 92, which is an arithmetic processing unit including a control unit and a calculation unit, as well as a payout side ROM 93, a payout side RAM 94, an interrupt circuit, a timer circuit, a data input/output circuit, and the like.

The payout-side ROM 93 is a memory such as a NOR flash memory and a NAND flash memory that does not require external power supply for storage and storage (that is, non-volatile storage means), and is used as a read-only memory. The payout-side ROM 93 stores various control programs executed by the payout-side CPU 92 and fixed value data.

The payout side RAM 94 is a memory (that is, a volatile storage means) such as an SRAM and a DRAM that needs to be supplied with electric power from the outside to retain the storage, and is used for both reading and writing. The payout side RAM 94 can be randomly accessed and has a shorter read time than the payout side ROM 93 when compared with the same data capacity. The payout side RAM 94 temporarily stores various data and the like for execution of the control program stored in the payout side ROM 93.

The payout side CPU 92 can perform bidirectional communication with the main side CPU 63. Upon receipt of the prize ball command from the main CPU 63, the payout side CPU 92 drives and controls the payout device 76 so that the number of game balls corresponding to the prize ball command is paid out. Further, the payout side CPU 92 monitors whether or not the payout of the game balls can be normally performed, and when it is specified that the payout of the game balls is not normally possible, the payout side RAM 94 is displayed. The payout device 76 is stopped even in the situation where the number of unpaid prize balls is stored. Further, the payout side CPU 92 transmits to the main side CPU 63 a payout restriction command indicating that the normal payout is not possible. When the main CPU 63 receives the payout restriction command, the symbol display device 41, the display light emitting unit 53, and the speaker unit 54 perform a notification indicating that it is not possible to normally pay out the game balls. As described above, the notification command is transmitted to the voice emission control device 81. As a state in which it is not possible to normally pay out the game balls, the lower plate 56a is filled with the game balls, the tank 75 has no balls filled with the game balls, and the payout device 76. Is not operating normally, there is a payout abnormal state, a main body open state in which the gaming machine main body 12 is opened from the outer frame 11, and a front door open state in which the front door frame 14 is opened from the inner frame 13. ..

An unillustrated full tank detection sensor is provided at an intermediate position of the game ball passage leading from the payout device 76 to the lower tray 56a, and the detection result of the full tank detection sensor is input to the payout side CPU 92. The payout side CPU 92 specifies that the gaming ball is in a full state when the gaming ball is continuously detected by the full tank detection sensor, and the state in which the gaming ball is continuously detected by the full tank detection sensor is released. In this case, it is specified that the full tank state has been released.

A ball non-detection sensor (not shown) is provided at an intermediate position of the game ball passage leading from the tank 75 to the payout device 76, and the detection result of the ball non-detection sensor is input to the payout side CPU 92. The payout side CPU 92 specifies that there is no ball when the game ball is not continuously detected by the ball non-detection sensor, and when the state where the game ball is not continuously detected by the ball no detection sensor is released. Specify that the ball-free state has been released.

The payout device 76 is provided with a payout detection sensor (not shown) for detecting the game balls paid out from the payout device 76, and the detection result of the payout detection sensor is input to the payout side CPU 92. The payout side CPU 92 specifies that one game ball has been paid out from the payout device 76 when the game ball is detected by the payout detection sensor. Further, the payout side CPU 92 specifies that the payout detection sensor is in the payout abnormal state when the payout detection sensor does not continuously detect the game ball despite the drive control of the payout device 76 so that the game ball is paid out. , When the state in which the game ball is not continuously detected by the payout detection sensor is released, it is specified that the abnormal payout state has been released.

A front door opening sensor 95 is provided on the front surface of the inner frame 13 (see FIG. 2), and the detection result of the front door opening sensor 95 is input to the payout side CPU 92. In this case, when the front door frame 14 is closed with respect to the inner frame 13, the front door opening sensor 95 transmits a close detection signal to the payout side CPU 92, and the front door frame 14 is opened with respect to the inner frame 13. In the case of, the front door opening sensor 95 transmits an opening detection signal to the payout side CPU 92. The payout side CPU 92 specifies that the front door frame 14 is in the closed state when receiving the closing detection signal from the front door opening sensor 95, and when receiving the opening detection signal from the front door opening sensor 95. The front door frame 14 is specified to be in the open state. Further, the payout-side CPU 92 transmits a front door opening command to the main CPU 63 at the timing specified that the front door frame 14 has changed from the closed state to the open state, and specifies that the front door frame 14 has changed from the open state to the closed state. The front door closing command is transmitted to the main CPU 63 at the timing. The main CPU 63 specifies that the front door frame 14 is in the open state when receiving the front door opening command, and specifies that the front door frame 14 is in the closing state when receiving the front door closing command.

A main body opening sensor 96 is provided on the front surface of the back pack unit 15 (see FIG. 2 ), and the detection result of the main body opening sensor 96 is input to the payout side CPU 92. In this case, when the gaming machine body 12 is closed with respect to the outer frame 11, the body opening sensor 96 transmits a closing detection signal to the payout side CPU 92, and the gaming machine body 12 is opened with respect to the outer frame 11. In some cases, the main body opening sensor 96 transmits an opening detection signal to the payout side CPU 92. The payout side CPU 92 specifies that the gaming machine main body 12 is in the closed state when receiving the closing detection signal from the main body opening sensor 96, and determines when the opening detection signal is received from the main body opening sensor 96. It specifies that the main body 12 is in the open state. Further, the payout side CPU 92 transmits a main body opening command to the main CPU 63 at a timing specified that the gaming machine main body 12 is changed from the closed state to the open state, and specifies that the gaming machine main body 12 is changed from the open state to the closed state. A main body closing command is transmitted to the main CPU 63 at a timing. The main CPU 63 identifies that the gaming machine body 12 is in the open state when receiving the body opening command, and identifies that the gaming machine body 12 is in the closing state when receiving the body closing command.

The timer interrupt process executed by the payout CPU 92 will be described with reference to the flowchart of FIG. The timer interrupt process is repeatedly activated at a predetermined cycle (for example, 2 milliseconds).

First, a full tank process is executed (step S701). In the process for full tank, as described above, it is determined whether or not the tank is in the full tank state based on the detection result of the full tank detection sensor, and in the case of the full tank state, the process for stopping the payout of the game balls. And the command indicating that the tank is full is transmitted to the main CPU 63. In addition, when the full tank state is released, processing for enabling the payout of gaming balls is executed, and at the same time, a command indicating that the full tank state has been released is transmitted to the main CPU 63.

After that, the ball non-use process is executed (step S702). In the ball non-use process, as described above, it is determined whether or not the ball is in a non-ball state based on the detection result of the ball non-detection sensor, and in the case of the non-ball state, a process for stopping the payout of the game ball Along with the execution, a command indicating that there is no ball is transmitted to the main CPU 63. Further, when the non-sphere state is released, processing for enabling payout of the game ball is executed, and a command indicating that the non-sphere state is released is transmitted to the main CPU 63.

After that, the payout abnormality monitoring processing is executed (step S703). In the payout abnormality monitoring processing, as described above, it is determined whether or not there is a payout abnormal state based on the detection result of the payout detection sensor, and in the case of the payout abnormal state, processing for stopping the payout of gaming balls is executed. At the same time, a command indicating that the dispensing is abnormal is sent to the main CPU 63. Also, when the payout abnormal state is canceled, processing for enabling the payout of gaming balls is executed, and a command indicating that the payout abnormal state has been canceled is transmitted to the main CPU 63.

Then, the front door opening monitoring process is executed (step S704). In the front door opening monitoring process, as described above, it is specified whether or not the front door frame 14 is in the open state based on the detection result of the front door open sensor 95, and when the front door frame 14 is in the open state, While executing the process of stopping the payout of the game balls, it sends a front door opening command to the main CPU 63. In addition, when the front door frame 14 is closed, processing for enabling payout of game balls is executed, and a front door closing command is transmitted to the main CPU 63.

After that, the main body opening monitoring process is executed (step S705). In the main body opening monitoring process, as described above, based on the detection result of the main body opening sensor 96, it is determined whether or not the gaming machine main body 12 is in the open state, and when the gaming machine main body 12 is in the open state, the game ball The process of stopping the payout of the main body is executed and the main body opening command is transmitted to the main CPU 63. In addition, when the gaming machine main body 12 is closed, processing for enabling the payout of gaming balls is executed, and a main body closing command is transmitted to the main CPU 63.

After that, the command reading process is executed (step S706). In the command reading process, a process of reading the prize ball command transmitted by the main CPU 63 is executed, and the prize ball command is stored in the payout side RAM 94. Then, after executing the prize ball setting process for adding the number corresponding to the received prize ball command to the unpaid prize ball number information in the payout side RAM 94 (step S707), the payout device 76 pays out the game balls. The payout control process for controlling the execution of is executed (step S708). In the payout control process, when the unpaid prize ball number information stored in the payout side RAM 94 has a value of 1 or more, the payout device 76 is driven and controlled, and the payout detection sensor detects one game ball. In this case, 1 is subtracted from the value of the prize ball number information. Then, when the value of the prize ball number information becomes "0", the drive control of the payout device 76 is stopped. After that, the external information setting process for controlling the start and end of the output of the external signal according to the processing results of the various processes executed in the timer interrupt process this time is executed (step S709).

Next, a configuration for externally outputting information from the pachinko machine 10 to the hall computer HC provided in the game hall will be described.

As shown in FIG. 2, the back pack unit 15 is provided with an external terminal board 97. The external terminal board 97 is provided with a large number of external terminals. Some of the external terminals are electrically connected to the main CPU 63 and some of the external terminals are provided. A plurality of external terminals are electrically connected to the payout side CPU 92. Since the main side CPU 63 and the payout side CPU 92 are electrically connected to the external terminal board 97 in this way, as shown in FIG. It is possible to output.

One external terminal of the external terminal board 97 is electrically connected to the front door open sensor 95, and one external terminal of the external terminal board 97 is electrically connected to the main body open sensor 96. In detail regarding the configuration of this electrical connection, a signal relay board 98 is provided at an intermediate position of a signal path from the front door opening sensor 95 to the payout side CPU 92. The signal relay board 98 is provided with a branch path SL2 branching from the signal path SL1 from the front door opening sensor 95 toward the payout side CPU 92. The branch path SL2 is connected to the external terminal for opening the front door of the external terminal board 97. Therefore, the electric signal corresponding to the detection result of the front door opening sensor 95 is input not only to the payout side CPU 92 but also to the external terminal for opening the front door of the external terminal board 97. As a result, a signal indicating whether or not the front door frame 14 is in the open state can be externally output to the hall computer HC without the control of the payout side CPU 92.

For details of the main body opening sensor 96, the signal relay board 98 is provided with a branching path SL4 branched from the signal path SL3 from the main body opening sensor 96 toward the payout side CPU 92. The branch path SL4 is connected to the external terminal for opening the main body of the external terminal board 97. Therefore, the electric signal corresponding to the detection result of the main body opening sensor 96 is input not only to the payout side CPU 92 but also to the external terminal for opening the main body of the external terminal board 97. As a result, a signal indicating whether or not the gaming machine main body 12 is in the open state can be externally output to the hall computer HC without the control of the payout side CPU 92.

Next, the contents of information externally output to the hall computer HC from the main CPU 63 and the payout CPU 92 will be described. First, the content of information output from the main CPU 63 to the hall computer HC will be described.

In the external information setting process (step S318) in the timer interrupt process (FIG. 11), the main CPU 63 sets output of information to each external terminal assigned to the main CPU 63 in the external terminal board 97. As information output from the main CPU 63 to the external terminal board 97, information indicating that the opening/closing execution mode is in effect, information indicating that the support mode is in the high-frequency support mode, and one game time have ended. And a predetermined number (for example, 100) of game balls from the game area PA through any one of the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first operating opening 33, and the second operating opening 34. Information indicating that the game ball has been discharged, information indicating that the game ball has entered the first operating port 33, and information that indicates that the game ball has entered the second operating port 34 are included. ..

In the external information setting process (step S709) in the timer interrupt process (FIG. 17), the payout side CPU 92 sets the output of information to each external terminal assigned to the payout side CPU 92 in the external terminal board 97. The information output from the payout side CPU 92 to the external terminal board 97 includes information indicating that 10 gaming balls have been paid out.

In the hall computer HC, according to various information received from the pachinko machine 10 through the external terminal board 97, it is possible to grasp the execution mode of paying out the game balls in the pachinko machine 10 or the like. For example,
・The payout rate, which is the ratio of the number of payouts of the game balls generated until 100 game balls are discharged from the game area PA of the pachinko machine ・The output in the normal game state that is not the opening/closing execution mode or the high frequency support mode Ball rate (hereinafter, this ball output rate is referred to as "B")
-Ball output rate in open/close execution mode-ball output rate in high frequency support mode-number of game times executed until 100 game balls are discharged from the game area PA of the pachinko machine 10 (hereinafter, this ratio is "S")
B-S x "the number of prize balls for winning in the first operating opening 33 and the second operating opening 34"
-The number of game balls entering the first operation port 33, which has occurred until 100 game balls are ejected from the game area PA of the pachinko machine 10 (hereinafter, this ratio is referred to as "S1")
-The number of game balls entering the second operation port 34 that have occurred until 100 game balls have been discharged from the game area PA of the pachinko machine 10 (hereinafter, this ratio is referred to as "S2")
B-(S1 x "number of prize balls for winning in first working port 33" + S2 x "number of prize balls for winning in second working port 34")
The probability of occurrence of the open/close execution mode per unit game time, the probability of occurrence of high frequency support mode per unit game time, etc. are calculated. As a result, the hall computer HC can manage the entering mode of the game ball in the game area PA of the pachinko machine 10. The number of prize balls is the number of game balls to be paid out when one game ball enters the corresponding ball input section.

<Structure for managing the winning mode of the game ball>
Next, a configuration for managing the game history using the management IC 66 will be described. First, the electrical configuration of the management IC 66 will be described with reference to the block diagram of FIG.

As described above, the MPU 62 of the main control device 60 includes the main CPU 63, the main ROM 64, the main RAM 65, and the management IC 66. Further, the MPU 62 is provided with the I/F 101 in addition to these, and is also provided with the reading terminal 68d already described.

The I/F 101 is an interface for transmitting/receiving a signal to/from a device external to the MPU 62. The I/F 101 is electrically connected to the main CPU 63 via the internal bus 103. The detection result from the sensors such as the ball detection sensors 42a to 49a and the command from the payout side CPU 92 are input to the MPU 62 through the input port of the I/F 101, and based on the input detection result and the content of the command. As described above, the main CPU 63 executes various processes. Further, when a signal is output to a device such as the drive unit 32b for special electric power as a result of execution of various processes in the main CPU 63, the signal is output through the output port of the I/F 101, and When a command is output to the payout side CPU 92 and the sound emission control device 81 as a result of the CPU 63 performing various processes, the command output is performed through the output port of the I/F 101.

The management IC 66 includes a management-side I/F 111, a management-side CPU 112, a management-side ROM 113, a management-side RAM 114, an RTC 115, a correspondence memory 116, a history memory 117, and a calculation result memory 131. Equipped with. These devices are connected to each other through an internal bus 66a provided in the management IC 66 so as to be capable of bidirectional communication.

The management-side I/F 111 receives various signals from the main CPU 63 via the signal path group 118 for unidirectional communication built in the MPU 62, and the signal path group 119 for unidirectional communication built in the MPU 62. It is an interface for transmitting various signals to the reading terminal 68d via the. Various signals from the main CPU 63 are input to the input port of the management I/F 111, and various signals to the reading terminal 68d are output from the output port of the management I/F 111. The main CPU 63 is electrically connected to the reading terminal 68d via the bidirectional communication signal path group 120 built in the MPU 62.

The management side CPU 112 is an arithmetic processing device including a control unit and an arithmetic unit. The management-side ROM 113 is a memory such as a NOR flash memory and a NAND flash memory that does not require external power supply for storage and storage (that is, nonvolatile storage means), and is used as a read-only memory. The management-side ROM 113 stores various control programs executed by the management-side CPU 112 and fixed value data. The management-side RAM 114 is a memory (that is, a volatile storage unit) such as an SRAM and a DRAM that needs to be supplied with electric power from the outside to retain the storage, and is used for both reading and writing. The management-side RAM 114 is capable of random access and has a shorter read time than the management-side ROM 113 when compared with the same data capacity. The management-side RAM 114 temporarily stores various data and the like for execution of the control program stored in the management-side ROM 113.

The RTC 115 is a real-time clock that constantly measures date information and time information, and outputs the measured date information and time information (hereinafter, also referred to as date and time information) according to an instruction from the management CPU 112. This is a possible configuration. The RTC 115 is provided with a backup power supply, and it is possible to measure the date information and the time information even while the power of the pachinko machine 10 is cut off.

The correspondence relationship memory 116 is a memory such as an SRAM and a DRAM that requires external power supply to retain the memory (that is, a volatile storage unit), and is used for both reading and writing. The correspondence memory 116 stores information on the correspondence between the buffers 122a to 122p provided in the input port 121 of the management-side I/F 111 and the types of signals input to the buffers 122a to 122p. Used for. Details of the contents of the correspondence memory 116 will be described later.

The history memory 117 is a memory such as a NOR flash memory and a NAND flash memory that does not require external power supply for storage and storage (that is, nonvolatile storage means), and is used for both reading and writing. The history memory 117 is used to store information regarding the game history received from the main CPU 63 through the management I/F 111. Details of the contents of the history memory 117 will be described later.

The operation result memory 131 is a memory such as a NOR flash memory and a NAND flash memory that does not require external power supply for storage, and is used for both reading and writing. The calculation result memory 131 is used to sequentially store various parameters calculated by the management-side CPU 112 using the history information stored in the history memory 117. The contents of various parameters stored in the calculation result memory 131 are sequentially displayed on the first to third notification display devices 69a to 69c and are output to the external device connected to the reading terminal 68d.

Next, the configuration of the input port 121 provided in the management-side I/F 111 will be described. FIG. 19 is an explanatory diagram for explaining the configuration of the input port 121 of the management-side I/F 111.

The input port 121 is provided with a plurality of buffers 122a to 122p. Specifically, first to sixteenth buffers 122a to 122p are provided. One type of signal can be input to each of the first to sixteenth buffers 122a to 122p through the signal paths 118a to 118p, and each of the first to sixteenth buffers 122a to 122p is an input target signal. Information of "0" is stored as the first data when is at the LOW level, and information of "1" is stored as the second data when the signal to be input is at the HI level. The relationship between the LOW and HI and the first data and the second data may be reversed.

The first signal corresponding to the detection result of the first winning opening detection sensor 42a is input to the first buffer 122a. In this case, the main CPU63 outputs the first signal of the LOW level in the situation where a new game ball is not detected by the first winning hole detection sensor 42a, and one game by the first winning hole detection sensor 42a. When the sphere is detected, the HI level first signal is output for a specific period. This specific period is a period sufficient for the management-side CPU 112 to specify that the HI-level first signal is input to the first buffer 122a.

The second signal corresponding to the detection result of the second winning opening detection sensor 43a is input to the second buffer 122b. In this case, the main CPU 63 outputs the second signal of the LOW level in a situation where a new game ball is not detected by the second winning opening detection sensor 43a, and one game is played by the second winning opening detection sensor 43a. When the sphere is detected, the HI level second signal is output for a specific period. This specific period is a period sufficient for the management-side CPU 112 to specify that the HI-level second signal is input to the second buffer 122b.

The third signal corresponding to the detection result of the third winning opening detection sensor 44a is input to the third buffer 122c. In this case, the main CPU 63 outputs a third signal of LOW level in a situation where a new game ball is not detected by the third winning hole detection sensor 44a, and one game is played by the third winning hole detection sensor 44a. When the sphere is detected, the HI level third signal is output for a specific period. This specific period is a period sufficient for the management-side CPU 112 to specify that the third signal of the HI level is input to the third buffer 122c.

The fourth signal corresponding to the detection result of the special electric power detection sensor 45a is input to the fourth buffer 122d. In this case, when the main CPU 63 outputs the fourth signal of LOW level in a situation where a new game ball is not detected by the special electric detection sensor 45a, and one game ball is detected by the special electric detection sensor 45a. And outputs a fourth signal of HI level for a specific period. This specific period is a period sufficient for the management side CPU 112 to specify that the HI level fourth signal is input to the fourth buffer 122d.

The fifth signal corresponding to the detection result of the first working port detection sensor 46a is input to the fifth buffer 122e. In this case, the main CPU 63 outputs a LOW level fifth signal in a situation where a new game ball is not detected by the first working opening detection sensor 46a, and one game is played by the first working opening detection sensor 46a. When the sphere is detected, the HI level fifth signal is output for a specific period. This specific period is a period sufficient for the management-side CPU 112 to specify that the HI-level fifth signal is input to the fifth buffer 122e.

The sixth signal corresponding to the detection result of the second operating port detection sensor 47a is input to the sixth buffer 122f. In this case, the main CPU 63 outputs a LOW level sixth signal in a situation where a new game ball is not detected by the second working opening detection sensor 47a, and one game is played by the second working opening detection sensor 47a. When the sphere is detected, the HI level sixth signal is output for a specific period. This specific period is a period sufficient for the management side CPU 112 to specify that the HI level sixth signal is input to the sixth buffer 122f.

The seventh signal corresponding to the detection result of the outlet detection sensor 48a is input to the seventh buffer 122g. In this case, the main CPU 63 outputs a LOW level seventh signal in a situation where a new game ball is not detected by the out-mouth detecting sensor 48a, and one game ball is detected by the out-mouth detecting sensor 48a. In that case, the seventh signal of HI level is output for a specific period. This specific period is a period sufficient for the management side CPU 112 to specify that the HI level seventh signal is input to the seventh buffer 122g.

An eighth signal corresponding to whether the open/close execution mode is in operation is input to the eighth buffer 122h. In this case, the main CPU 63 continuously outputs the eighth signal of LOW level in the situation not in the opening/closing execution mode, and continuously outputs the eighth signal of HI level in the situation in the opening/closing execution mode.

A ninth signal corresponding to whether or not the high frequency support mode is in operation is input to the ninth buffer 122i. In this case, the main CPU 63 continues to output the LOW-level ninth signal in the situation not in the high-frequency support mode, and continuously outputs the HI-level ninth signal in the situation in the high-frequency support mode.

A tenth signal corresponding to whether or not the front door frame 14 is open is input to the tenth buffer 122j. In this case, the main CPU 63 continuously outputs the LOW level tenth signal when the front door frame 14 is closed, and continues the HI level tenth signal when the front door frame 14 is open. And output.

The eleventh signal corresponding to whether or not the game time has started is input to the eleventh buffer 122k. In this case, the main CPU 63 continuously outputs the LOW level eleventh signal before the game time is started, and outputs the HI level eleventh signal for a specific period when the game time is started. To do. This specific period is a period sufficient for the management-side CPU 112 to specify that the HI-level eleventh signal is input to the eleventh buffer 122k.

A set value update signal is input to the fifteenth buffer 122o for causing the management CPU 112 to recognize that the main CPU 63 has newly set the setting state of the pachinko machine 10. In this case, when the main CPU 63 outputs a LOW level set value update signal in a situation where the setting state of the pachinko machine 10 is not newly set, and the setting state of the pachinko machine 10 is newly set. In addition, the HI level set value update signal is output for the number of pulse signals corresponding to the newly set set value for a specific period. This specific period is a period sufficient for the management CPU 112 to specify that the HI level set value update signal is input to the fifteenth buffer 122o.

The sixteenth buffer 122p has an output instruction signal for causing the management-side CPU 112 to recognize the trigger for outputting the history information stored in the history memory 117 and the various parameters stored in the calculation result memory 131 to the reading terminal 68d. Is entered. In this case, the main CPU 63 outputs a LOW level output instruction signal in a situation where it is not necessary to output history information, and outputs a HI level output instruction signal for a specific period when it is necessary to output history information. To do. The specific period is a period sufficient for the management-side CPU 112 to specify that the HI level output instruction signal is input to the sixteenth buffer 122p.

Although the twelfth buffer 122l, the thirteenth buffer 122m, and the fourteenth buffer 122n can input signals from the main CPU 63, the pachinko machine 10 is blank in which normal signals are not input. In this way, as the input port 121 of the management-side I/F 111, the number of buffers 122a to 122p, which are larger than the types of signals output from the main CPU 63 to the management IC 66 in the pachinko machine 10, are provided. The management IC 66 can be used for a model different from the pachinko machine 10. This makes it possible to improve the versatility of the management IC 66. Incidentally, signal paths 118a to 118p are formed between the main CPU 63 and each of the first to sixteenth buffers 122a to 122p in a one-to-one correspondence with the first to sixteenth buffers 122a to 122p. However, the configuration is not limited to this, and the signal paths 118l to 118n may not be formed between the buffers 122l to 122n to be blanked.

Whether the set value update signal is input to the fifteenth buffer 122o and the output instruction signal is input to the sixteenth buffer 122p are determined at the design stage of the management IC 66, and an instruction from the main CPU 63 is received. Instead, the management-side CPU 112 can specify that the set value update signal is input to the fifteenth buffer 122o and that the output instruction signal is input to the sixteenth buffer 122p. On the other hand, what kind of signal is input to the first to fourteenth buffers 122a to 122n has not been determined at the design stage of the management IC 66, and these kinds of signals are instructed by the main CPU 63. As a result, the CPU 112 on the management side specifies. Although the details of the types of these signals in the management-side CPU 112 will be described later, when control is started in the main-side CPU 63 and the management-side CPU 112 with the start of supply of operating power to the MPU 62, the main-side CPU 63 causes the management-side CPU 112 to perform control. It is performed by transmitting a type identification command to the. In this case, the information on the types of various signals provided by the type identification command is stored in the correspondence memory 116, and when the types of various signals are specified by the management side CPU 112 in the situation where the operating power is supplied, The information stored in the correspondence memory 116 is referred to.

FIG. 20 is an explanatory diagram for explaining the configuration of the correspondence memory 116. In the correspondence memory 116, first to fourteenth correspondence areas 123a to 123n are provided in a one-to-one correspondence with the first to fourteenth buffers 122a to 122n provided in the input port 121 of the management-side I/F 111. It is provided.

In the first correspondence area 123a, information indicating the general winning opening 31 is stored as information for the management-side CPU 112 to specify the type of signal input to the first buffer 122a. In addition, in the first correspondence area 123a, information indicating that it is the general winning opening 31 and information on the number of gaming balls to be paid out when one gaming ball enters the general winning opening 31 (10 pieces) Is stored. In the second correspondence area 123b, information indicating the general winning opening 31 is stored as information for the management-side CPU 112 to specify the type of signal input to the second buffer 122b. In addition, in the second correspondence area 123b, information indicating that it is the general winning opening 31 and information (10 pieces) of the number of gaming balls to be paid out when one gaming ball enters the general winning opening 31 are also provided. Is stored. In the third correspondence area 123c, information indicating the general winning opening 31 is stored as information for the management-side CPU 112 to specify the type of signal input to the third buffer 122c. In addition, in the third correspondence area 123c, information indicating that it is the general winning opening 31 and information (10 pieces) on the number of gaming balls to be paid out when one gaming ball enters the general winning opening 31 are also provided. Is stored.

In the fourth correspondence area 123d, information indicating the special electric prize winning device 32 is stored as information for the management-side CPU 112 to specify the type of signal input to the fourth buffer 122d. In addition, in the fourth correspondence area 123d, information indicating that it is the special electric prize winning device 32 and information on the number of game balls to be paid out when one game ball enters the special electric prize winning device 32 (15 pieces) Is stored. Information indicating the first operation port 33 is stored in the fifth correspondence area 123e as information for the management-side CPU 112 to specify the type of signal input to the fifth buffer 122e. Further, in the fifth correspondence area 123e, together with information indicating that it is the first operation port 33, information on the number of game balls to be paid out when one game ball enters the first operation port 33 (1 ) Is also stored. In the sixth correspondence area 123f, information indicating the second operating port 34 is stored as information for the management-side CPU 112 to specify the type of signal input to the sixth buffer 122f. Further, in the sixth correspondence area 123f, together with information indicating that it is the second operation port 34, information on the number of game balls to be paid out when one game ball enters the second operation port 34 (1 ) Is also stored. Information indicating the outlet 24a is stored in the seventh correspondence area 123g as information for the management-side CPU 112 to specify the type of signal input to the seventh buffer 122g.

Information indicating the open/close execution mode is stored in the eighth correspondence area 123h as information for the management-side CPU 112 to specify the type of signal input to the eighth buffer 122h. In the ninth correspondence area 123i, information indicating the high frequency support mode is stored as information for the management CPU 112 to specify the type of signal input to the ninth buffer 122i. In the tenth correspondence area 123j, information indicating the front door frame 14 is stored as information for the management-side CPU 112 to specify the type of signal input to the tenth buffer 122j. In the eleventh correspondence area 123k, as the information for the management side CPU 112 to specify the type of the signal input to the eleventh buffer 122k, information indicating that the game time is started is stored.

In the twelfth correspondence area 123l, as information for specifying the type of signal input to the twelfth buffer 122l by the management side CPU 112, information indicating a blank that does not correspond to any is stored. In the thirteenth correspondence area 123m, as the information for specifying the type of the signal input to the thirteenth buffer 122m by the management side CPU 112, information indicating a blank that does not correspond to any is stored. In the fourteenth correspondence area 123n, as information for specifying the type of signal input to the fourteenth buffer 122n by the management-side CPU 112, information indicating a blank that does not correspond to any is stored.

As described above, what kind of signal is input to the first to fourteenth buffers 122a to 122n is specified by the management-side CPU 112 by receiving an instruction from the main-side CPU 63. The management IC 66 can be used for a model different from the pachinko machine 10. This makes it possible to improve the versatility of the management IC 66.

Also, instead of outputting the information for recognizing the signal type to the first to fourteenth buffers 122a to 122n each time the signal corresponding to the storage of history information is output, the signal type is recognized in advance. And the information for specifying the types of signals input to the first to fourteenth buffers 122a to 122n on the management side CPU 112 based on the output information is stored in the correspondence relationship memory 116. It is a configuration. As a result, compared with the configuration in which the information for recognizing the type of the signal is output each time the signal output corresponding to the storage of the history information is output to the first to fourteenth buffers 122a to 122n, It is possible to reduce the amount of information output from the side CPU 63 to the management side CPU 112.

In addition, the output of information for specifying the type of signal input to the first to fourteenth buffers 122a to 122n by the management-side CPU 112 is performed at the start of supply of operating power. As a result, in the situation where a game is started on the pachinko machine 10, it becomes possible for the management-side CPU 112 to specify the types of signals input to the first to fourteenth buffers 122a to 122n.

Further, information setting that the setting value update signal is input to the fifteenth buffer 122o and information setting that the output instruction signal is input to the sixteenth buffer 122p are performed in the design stage of the management IC 66. As a result, not only the pachinko machine 10 but also other types of pachinko machines that use the management IC 66 can reliably use the set value update signal and the output instruction signal for the fifteenth buffer 122o and the sixteenth buffer 122p. It is possible to omit the processing for specifying the type of signal input to the. Therefore, it is possible to reduce the processing load of the processing for specifying the type of the signal.

Next, the history memory 117 of the management IC 66 will be described. FIG. 21 is an explanatory diagram for explaining the configuration of the history memory 117.

The history memory 117 is provided with a history area 124 for sequentially storing history information. In the history area 124, a plurality of pieces of pointer information are set in serial numbers, and a history information storage area 125 is set in a one-to-one correspondence with each pointer information. The history information storage area 125 can store a combination of RTC information and correspondence information. In this case, each history information storage area 125 has a data capacity of 2 bytes, a data capacity of 1 byte is allocated as an area for storing RTC information, and an area for storing correspondence information. A data capacity of 1 byte is assigned. When it is necessary to store the correspondence information according to the signals input to the first to fourteenth buffers 122a to 122n (actually, in the case of the pachinko machine 10, the first to eleventh buffers 122a to 122k) First, the date and time information measured by the current RTC 115 is stored in the area for storing the RTC information of the history information storage area 125 corresponding to the pointer information which is the current writing target. After that, the correspondence relationship information corresponding to the buffers 122a to 122n that triggered the information storage this time is read from the correspondence relationship areas 123a to 123n corresponding to the buffers 122a to 122n in the correspondence relationship memory 116, and the read correspondence relationship information. Is stored in the area for storing the correspondence information of the history information storage area 125 corresponding to the pointer information which is the current writing target.

Regarding the correspondence information stored in the history information storage area 125, specifically, the first to seventh buffers 122a to 122g are input with the signals corresponding to the detection results of the ball detection sensors 42a to 48a as described above. Therefore, the information corresponding to the types of the ball detection sensors 42a to 48a is stored in the first to seventh correspondence areas 123a to 123g in the correspondence memory 116. More specifically, the information corresponding to the type of the ball entering portion corresponding to each of the ball detecting sensors 42a to 48a is stored in the first to seventh correspondence areas 123a to 123g. As described above, in the pachinko machine 10, the first to third winning opening detection sensors 42a to 44a are all for detecting the game balls that have entered the general winning opening 31, so these first to third winning openings are provided. Information indicating the general winning opening 31 is stored in each of the first to third correspondence areas 123a to 123c corresponding to the detection sensors 42a to 44a. Further, information indicating that it is the special electricity winning device 32 is stored in the fourth correspondence area 123d, and information indicating that it is the first operation port 33 is stored in the fifth correspondence area 123e. The sixth correspondence relationship area 123f stores information indicating the second operation port 34, and the seventh correspondence relationship area 123g stores information indicating the outlet port 24a. When the buffers 122a to 122n that have triggered the information storage this time are any of the first to seventh buffers 122a to 122g, the information on the type of the ball entering portion corresponding to the buffers 122a to 122g is the first to the first. It is read from any of the seventh correspondence areas 123a to 123g, and the read information on the type of the ball entering portion is stored as it is in the area for storing the correspondence information of the history information storage area 125.

On the other hand, a signal indicating whether the eighth buffer 122h is in the open/close execution mode is input, a signal indicating whether the ninth buffer 122i is in the high frequency support mode is input, and the tenth buffer 122j is A signal indicating whether or not the front door frame 14 is being opened is input, and a signal indicating whether or not the game time has started is input to the eleventh buffer 122k. Accordingly, the eighth correspondence area 123h stores information indicating the open/close execution mode, the ninth correspondence area 123i stores information indicating the high-frequency support mode, and the tenth correspondence area 123h. Information indicating that it is the front door frame 14 is stored in 123j, and information indicating that it is a game time is stored in the eleventh correspondence area 123k.

As described above, the main CPU 63 continuously outputs the LOW level eighth signal in the situation where the open/close execution mode is not set, and continuously outputs the HI level eighth signal in the situation where the open/close execution mode is set. The side CPU 112 identifies that the opening/closing execution mode has started when the eighth signal changes from the LOW level to the HI level, and identifies that the opening/closing execution mode has ended when the eighth signal changes from the HI level to the LOW level. It becomes possible. Then, regardless of whether the eighth signal changes from the LOW level to the HI level or when the HI level changes to the LOW level, the management-side CPU 112 generates a trigger to store the correspondence information in the history information storage area 125. Identify as done. That is, when the eighth signal changes from the LOW level to the HI level, not only the information indicating the open/close execution mode read from the eighth correspondence area 123h, but also the start information is stored together with the history information storage area 125. It is stored in the area for storing the correspondence information of. Further, when the eighth signal changes from the HI level to the LOW level, not only the information indicating the open/close execution mode read from the eighth correspondence area 123h but also the end information is also recorded together with the history information storage area 125. It is stored in the area for storing the correspondence information of.

As described above, the main CPU 63 continuously outputs the LOW-level ninth signal in the situation not in the high-frequency support mode, and continuously outputs the HI-level ninth signal in the situation in the high-frequency support mode. The managing CPU 112 identifies that the high-frequency support mode is started when the ninth signal changes from the LOW level to the HI level, and ends the high-frequency support mode when the ninth signal changes from the HI level to the LOW level. It is possible to specify that it has been done. Then, regardless of whether the ninth signal changes from the LOW level to the HI level or when the HI level changes to the LOW level, the management-side CPU 112 generates a trigger to store the correspondence information in the history information storage area 125. Identify as done. That is, when the ninth signal changes from the LOW level to the HI level, not only the information indicating the high frequency support mode read from the ninth correspondence area 123i, but also the start information is stored in the history information storage area. It is stored in the area for storing 125 correspondence information. Further, when the ninth signal changes from the HI level to the LOW level, not only the information indicating the high frequency support mode read from the ninth correspondence area 123i but also the end information is recorded in the history information storage area. It is stored in the area for storing 125 correspondence information.

As described above, the main CPU 63 continuously outputs the LOW level tenth signal when the front door frame 14 is in the closed state, and outputs the HI level tenth signal when the front door frame 14 is in the open state. Because the continuous output is performed, the management-side CPU 112 specifies that the front door frame 14 has been opened when the tenth signal changes from the LOW level to the HI level, and when the tenth signal changes from the HI level to the LOW level. It is possible to specify that the front door frame 14 is closed. Then, both when the tenth signal changes from the LOW level to the HI level and when the HI level changes to the LOW level, the management-side CPU 112 causes the history information storage area 125 to store the correspondence information. Identify as done. That is, when the tenth signal changes from the LOW level to the HI level, not only the information indicating the front door frame 14 read from the tenth correspondence area 123j but also the opening start information is stored together with the history information. It is stored in the area for storing the correspondence information of the area 125. Further, when the tenth signal changes from the HI level to the LOW level, not only the information indicating the front door frame 14 read from the tenth correspondence area 123j but also the opening end information is stored together with the history information. It is stored in the area for storing the correspondence information of the area 125.

As described above, the main CPU 63 continues to output the LOW level eleventh signal until the game time start timing, and when the game time start timing is reached, the HI level eleventh signal is output for a specific period. Output a signal. Therefore, the management side CPU 112 specifies that the game time has started when the 11th signal changes from the LOW level to the HI level. In other words, when the eleventh signal changes from the LOW level to the HI level, the information indicating the game time read from the eleventh correspondence relation area 123k is stored as the correspondence relation information in the history information storage area 125. Store in the area.

The history information storage area 125 can store all history information generated during the 10 consecutive business days in which the game balls are continuously emitted from the pachinko machine 10 from opening to closing. It is provided for a few minutes. For example, if the history information is generated 60,000 times a day, 600,000 or more history information storage areas 125 are provided. As a result, all history information can be stored and held in the history memory 117 for at least 10 days.

The history memory 117 is provided with a pointer area 126 in addition to the history area 124. The pointer area 126 stores information for the management CPU 112 to specify the pointer information that is the current write target in the history memory 117. Specifically, at the shipping stage of the pachinko machine 10, information for designating the pointer information “0” as the writing target is set in the pointer area 126. Then, each time one piece of history information is newly stored in the history information storage area 125, the information in the pointer area 126 is updated so that the value of the pointer information to be written is incremented by one. If the history information is stored in the history information storage area 125 corresponding to the last-order pointer information and the last-order pointer information is written, the pointer information of “0” is set as the pointer. The information in the usage area 126 is updated. As a result, when a history information storage trigger occurs that exceeds the number of history information items that can be stored, new history information is overwritten in order from the history information storage area 125 in which old history information is stored. Become.

Further, when the history information is read from the history memory 117 by the external device, all the history information storage area 125 is cleared to “0”, and the pointer information of “0” becomes the writing target. The information in the pointer area 126 is updated. As a result, it is possible to prevent the history information that was once read from becoming read again.

Next, a specific processing configuration for managing the game history using the management IC 66 will be described. First, a processing configuration for storing information on the correspondence between the first to fourteenth buffers 122a to 122n provided in the input port 121 of the management-side I/F 111 and the types of signals in the correspondence memory 116 will be described. FIG. 22 is a flowchart showing the recognition process executed by the main CPU 63. The recognition process is executed in step S111 in the main process (FIG. 9).

First, "14" is set to the recognition output counter provided in the main RAM 65 (step S801). The output counter for recognition recognizes which type of signals the first to fourteenth buffers 122a to 122n of the input port 121 of the management-side I/F 111 correspond to, and outputs the remaining information output to the management-side CPU 112. Is a counter for the main CPU 63 to specify the required number of times. As described above, 14 of the first to fourteenth buffers 122a to 122n are targets of signal type recognition, so "14" is set in the recognition output counter.

Then, the output process of the identification start command is executed (step S802). The main CPU 63 outputs various commands to the management CPU 112 in order to make the management CPU 112 recognize which type of signal the first to fourteenth buffers 122a to 122n correspond to. When outputting this command, the first to eighth signals input to the first to eighth buffers 122a to 122h are used. That is, using the first to eighth signals (that is, the first to eighth signal paths 118a to 118h) used to instruct the management-side CPU 112 to store history information, the first to fourteenth buffers 122a are used. A command is output to cause the management CPU 112 to recognize which type of signal corresponds to 122n. This reduces the number of signal paths as compared with a configuration in which a signal path for performing the command output is provided separately from the signal paths 118a to 118p for outputting signals to the first to sixteenth buffers 122a to 122p. It becomes possible to simplify the configuration. The identification start command has an 8-bit data capacity, and the data of each bit is input to the first to eighth buffers 122a to 122h as the first to eighth signals, respectively. Further, in the output process of the identification start command, the output state of the ninth signal is switched to the HI level at the timing when the output of the identification start command is started in order to make the management CPU 112 recognize that the new command has been transmitted. Further, the output period of the identification start command and the period of maintaining the output state of the ninth signal at the HI level are set to a period sufficient for the management-side CPU 112 to recognize the output state of the identification start command and the ninth signal. Has been done. Upon receiving the identification start command, the management-side CPU 112 should start the process for storing the information on the correspondence between the first to fourteenth buffers 122a to 122n and the types of signals in the correspondence memory 116. Identify.

Then, the type identification command corresponding to the current value of the recognition output counter of the main RAM 65 is read from the main ROM 64 (step S803). In this case, the first buffer 122a corresponds to the first to fourteenth buffers 122a to 122n so that the signal type setting target is first and then the (n+1)th buffer is the signal type setting target after the nth buffer. The signal type recognition setting is set. Therefore, if the recognition output counter is "14" to "12", the type identification command indicating the general winning opening 31 and the number of prize balls is read out, and if the recognition output counter is "11", the special prize winning The type identification command indicating the device 32 and the number of prize balls is read, and if the recognition output counter is "10", the type identification command indicating the first operation port 33 and the number of prize balls is read. If the recognition output counter is "9", it is the second operation port 34, and the type identification command indicating the number of prize balls is read, and if the recognition output counter is "8", it is the out port 24a. The type identification command shown is read out, and if the recognition output counter is "7", the type identification command indicating the open/close execution mode is read out, and if the recognition output counter is "6", it is the high frequency support mode. If the recognition output counter is "5", the type identification command indicating the front door frame 14 is read, and if the recognition output counter is "4", it is a game game. Is read out, and if the recognition output counter is "3" to "1", the type identification command indicating blank is read out.

Then, the output process of the read type identification command is executed (step S804). The type identification command has an 8-bit data capacity similarly to the identification start command, and the data of each bit is input to the first to eighth buffers 122a to 122h as the first to eighth signals, respectively. Further, in the output processing of the identification type command, the output state of the ninth signal is switched to the HI level at the timing when the output of the identification type command is started so that the management side CPU 112 recognizes that a new command has been transmitted. Further, the output period of the identification type command and the period of maintaining the output state of the ninth signal at the HI level are set to a period sufficient for the management side CPU 112 to recognize the output state of the identification type command and the ninth signal. Has been done. By receiving the identification type command, the management-side CPU 112 responds to the identification type command to the corresponding relationship areas 123a to 123n corresponding to the buffer which is the current setting target among the first to fourteenth buffers 122a to 122n. Information to be stored.

After that, the value of the recognition output counter of the main RAM 65 is decremented by 1 (step S805), and it is determined whether the value of the recognition output counter after the decrement is 1 is "0" (step S806). When the value of the recognition output counter is 1 or more (step S806: NO), a process for outputting a type identification command corresponding to the value of the recognition output counter after subtraction of 1 is executed (step S803 and Step S804).

On the other hand, if the value of the recognition output counter is “0” (step S806: YES), the output process of the identification end command is executed (step S807). The identification end command has an 8-bit data capacity, and the data of each bit is input to the first to eighth buffers 122a to 122h as the first to eighth signals, respectively. Further, in the output processing of the identification end command, the output state of the ninth signal is switched to the HI level at the timing when the output of the identification end command is started in order to make the management CPU 112 recognize that the new command has been transmitted. The output period of the identification end command and the period of maintaining the output state of the ninth signal at the HI level are set to a period sufficient for the management-side CPU 112 to recognize the output state of the identification end command and the ninth signal. Has been done. Upon receiving the identification end command, the management-side CPU 112 identifies that the processing for storing the information on the correspondence relationship between the first to fourteenth buffers 122a to 122n and the signal type in the correspondence relationship memory 116 is completed. To do.

Next, the management processing executed by the management CPU 112 will be described with reference to the flowchart of FIG. The management process is started when the supply of operating power to the management CPU 112 is started. The processing speed of the management CPU 112 is higher than that of the main CPU 63, and the next timer interrupt processing (FIG. 11) is started after the main CPU 63 starts one timer interrupt processing (FIG. 11). By the time the process starts, the combination of the processes from step S908 onward in the management process is executed 16 times or more.

First, it is determined whether an identification start command has been received from the main CPU 63 (step S901). When the identification start command has not been received (step S901: NO), the setting update recognition process is executed (step S902), and the process returns to step S901. Although details will be described later, in the setting update recognition process, when the main CPU 63 newly sets the setting state of the pachinko machine 10, the corresponding process is executed.

When the identification start command is received from the main CPU 63 (step S901: YES), the value of the setting target counter provided in the management RAM 114 is cleared to “0” (step S903). The setting target counter is a counter for the management-side CPU 112 to specify the type of the buffer 122a to 122n for which the signal type is set. The first buffer 122a is the target for setting the signal type first, and then the n+1th buffer is the target for setting the signal type after the nth buffer.

After that, on condition that the type identification command is received from the main CPU 63 (step S904: YES), the correspondence relationship setting process is executed (step S905). In the correspondence relation setting process, of the first to fourteenth correspondence relation areas 123a to 123n of the correspondence relation memory 116, in the correspondence relation area corresponding to the current value of the setting target counter of the management side RAM 114, the type identification received this time is identified. Stores the signal type information set in the command. Then, the value of the setting target counter of the management RAM 114 is incremented by 1 (step S906).

If a negative determination is made in step S904, or if the processing of step S906 is executed, it is determined whether or not an identification end command has been received from the main CPU 63 (step S907). If the identification end command has not been received (step S907: NO), the process returns to step S904, and on condition that the type identification command is newly received from the main CPU 63 (step S904: YES), steps S905 and S906 are executed. Execute the process again.

When the identification end command is received from the main CPU 63 (step S907: YES), the processes of steps S908 to S910 are repeatedly executed. Although details will be described later, in step S908, history setting processing for storing history information corresponding to the type of signal received from the main CPU 63 in the history memory 117 is executed. Although details will be described later, in step S909, various parameters are calculated using the history information stored in the history memory 117, and the calculation results are notified by the first to third notification display devices 69a to 69c. Display output processing for executing. In step S910, an external output process for outputting the history information stored in the history memory 117 and various parameters stored in the operation result memory 131 to the reading terminal 68d, which will be described in detail later, is executed.

FIG. 24 is a time chart showing a state in which information on the correspondence between the first to fourteenth buffers 122a to 122n and the types of signals input to these buffers 122a to 122n is stored in the correspondence memory 116. FIG. 24A shows a period during which a command is output from the main CPU 63 to the management CPU 112 using the first to eighth signals (that is, the first to eighth signal paths 118a to 118h). FIG. 24B shows a period during which the output state of the ninth signal is at the HI level, and FIG. 24C shows the first to fourteenth buffers 122a to 122n and the types of signals input to these buffers 122a to 122n. 24D shows the execution period of the identification state in which the process for identifying the correspondence is executed, and FIG. 24D shows the timing at which the management CPU 112 executes the correspondence setting process (step S905).

When the supply of the operating power to the main CPU 63 and the management CPU 112 is started, the output of the identification start command using the first to eighth signals is started at the timing of t1 as shown in FIG. It Further, at the timing of t1, the output state of the ninth signal is changed from the LOW level to the HI level as shown in FIG. After that, at the timing of t2 in which the output of the identification start command is continued, as shown in FIG. 24B, the output state of the ninth signal is changed from the HI level to the LOW level. The management-side CPU 112 confirms that the output state of the ninth signal is changed from the HI level to the LOW level, thereby specifying that the command is transmitted from the main-side CPU 63, and the first to eighth buffers 122a to 122h. The contents of the command received from the main CPU 63 are grasped by confirming the information of. In this case, since the identification start command has been received, the management-side CPU 112 enters the identification state by making a positive determination in step S901 of the management process (FIG. 23). Thereafter, at the timing of t3, the output of the identification start command is stopped as shown in FIG.

Then, at timing t4, as shown in FIG. 24A, the output of the first type identification command using the first to eighth signals is started. Further, at the timing of t4, the output state of the ninth signal is changed from the LOW level to the HI level as shown in FIG. After that, at the timing of t5, which is the situation where the type identification command is continuously output, the output state of the ninth signal is changed from the HI level to the LOW level as shown in FIG. The management-side CPU 112 identifies that the command has been transmitted from the main-side CPU 63 by confirming that the output state of the ninth signal has been changed from the HI level to the LOW level, and the first-eighth buffers 122a to 122h By confirming the information, the content of the command received from the main CPU 63 is grasped. In this case, since the first type identification command has been received, the management-side CPU 112 executes the correspondence setting process at the timing of t5 as shown in FIG. In the correspondence relationship setting process, information indicating the general winning opening 31 and information on the number of prize balls are stored in the first correspondence area 123a of the correspondence memory 116. After that, at the timing of t6, the output of the type identification command is stopped as shown in FIG.

After that, in each of the timing of t7 to the timing of t9, the timing of t10 to the timing of t12, the timing of t13 to the timing of t15, and the timing of t16 to the timing of t18, similarly to the timing of t4 to the timing of t6, The management side CPU 112 executes the correspondence relationship setting process corresponding to the type identification command output from the side CPU 63. In this case, the correspondence setting process corresponding to the 14th type identification command is completed from timing t16 to timing t18.

After that, at the timing of t19, as shown in FIG. 24A, the output of the identification end command using the first to eighth signals is started. Further, at the timing of t19, the output state of the ninth signal is changed from the LOW level to the HI level as shown in FIG. After that, at the timing of t20 in which the output of the identification end command is continued, the output state of the ninth signal is changed from the HI level to the LOW level as shown in FIG. 24(b). The management-side CPU 112 identifies that the command has been transmitted from the main-side CPU 63 by confirming that the output state of the ninth signal has been changed from the HI level to the LOW level, and the first-eighth buffers 122a to 122h By confirming the information, the content of the command received from the main CPU 63 is grasped. In this case, since the identification end command has been received, the identification state of the management-side CPU 112 ends at the timing t20 as shown in FIG. Then, at the timing of t21, the output of the identification end command is stopped as shown in FIG.

In order to instruct the management-side CPU 112 to store history information, the management-side CPU 112 is configured to recognize whether or not the command is output using the ninth signal as described above. Even if the command is output using the first to eighth signals (that is, the first to eighth signal paths) used, it is clear to the management side CPU 112 that the command is being output. It becomes possible to recognize.

Next, a processing configuration for storing history information in the history memory 117 will be described. FIG. 25 is a flowchart showing the management output process executed by the main CPU 63. The management output process is executed in step S319 in the timer interrupt process (FIG. 11).

First, "11" is set in the managed counter provided in the main RAM 65 (step S1001). The management target counter specifies, by the main CPU 63, whether or not there is a management target that is not a target for specifying whether or not the signal output state to the management side CPU 112 should be changed in this management output process. At the same time, it is a counter for the main CPU 63 to specify which management target should change the signal output state to the management CPU 112. In the one-time management output process, the main CPU 63 specifies whether or not the signal output state to the management CPU 112 should be changed. The management targets are the seven ball detection sensors 42a to 48a. There are a total of 11 whether the opening/closing execution mode is executed, the high-frequency support mode is executed, the front door frame 14 is opened/closed, and the game time is started. Therefore, first, "11" is set in the managed counter.

Then, it is determined whether the output state of the signal to the management-side CPU 112 for the management target corresponding to the current value of the management target counter is the HI level (step S1002). When it is not the HI level (step S1002: NO), it is determined whether or not the value of the managed counter is 5 or more, so that the entry detection sensors 42a having seven managed objects corresponding to the value of the managed counter are detected. To 48a are specified (step S1003).

When an affirmative determination is made in step S1003, it is determined whether or not the output flag of the main RAM 65 corresponding to the value of the managed counter is set to "1" (step S1004). Specifically, when the value of the managed counter is “11” and corresponds to the first winning hole detection sensor 42a, it is determined whether or not “1” is set in the first output flag, When the value of the managed counter is “10” and corresponds to the second winning hole detection sensor 43a, it is determined whether or not “1” is set in the second output flag, and the value of the managed counter is determined. Is "9" and corresponds to the third winning opening detection sensor 44a, it is determined whether or not "1" is set in the third output flag, and the value of the managed counter is "8". If it corresponds to the special electric power detection sensor 45a, it is determined whether or not "1" is set in the fourth output flag, and the value of the managed counter is "7", and the first working opening detection sensor 46a. If it corresponds to, it is determined whether or not "1" is set in the fifth output flag, the value of the managed counter is "6", and it corresponds to the second working port detection sensor 47a. In this case, it is determined whether or not the sixth output flag is set to "1", and when the value of the managed counter is "5" and it corresponds to the outlet 24a, the seventh output flag is set to " It is determined whether "1" is set. As described above, the first to seventh output flags are set to "1" in the incoming ball detection process (FIG. 15).

When "1" is set in the output flag corresponding to the value of the managed counter (step S1004: YES), the output state of the signal corresponding to the value of the managed counter among the first to seventh signals is set to the HI level. Is set (step S1005). After that, the output flag corresponding to the value of the managed counter is cleared to "0" (step S1006).

When a negative determination is made in step S1003, it is determined whether a trigger for switching the output state of the signal corresponding to the value of the managed counter to the HI level has occurred (step S1007). Specifically, when the value of the managed counter is "4", it is determined whether or not the transition to the open/close execution mode has occurred, and when the value of the managed counter is "3", it is high. It is determined whether or not the transition to the frequency support mode has occurred, and when the value of the managed counter is “2”, it is determined whether the front door frame 14 is in the open state, and the managed counter When the value is "1", it is determined whether the game time has started by determining whether "1" is set in the eleventh output flag. If an affirmative decision is made in step S1007, the output state of the signal corresponding to the value of the managed counter is set to the HI level (step S1008). If the process of step S1008 is executed when the value of the managed counter is "1", the eleventh output flag is cleared to "0".

When an affirmative determination is made in step S1002, it is determined whether or not a trigger for switching the output state of the signal corresponding to the value of the managed counter to the LOW level has occurred (step S1009). Specifically, when the value of the management target counter is 5 or more or "1" and the current management target is any of the ball entry detection sensors 42a to 48a or the start of the game time, the first to seventh signals And it is determined whether or not the HI output continuation period (specifically, 10 milliseconds) has elapsed since the output state of the signal corresponding to the value of the managed counter in the 11th signal was switched from the LOW level to the HI level. .. This HI output continuation period is set to a period longer than the longest processing interval of the history setting process (step S908) of the management process (FIG. 23) in the management side CPU 112, and the output of the signal switched from the LOW level to the HI level It is a period in which the state can be reliably specified by the management CPU 112. When the value of the managed counter is “4” and the current managed object is the open/close execution mode, it is determined whether the open/close execution mode has ended, and the value of the managed counter is “3”. When the current management target is the high-frequency support mode, it is determined whether the high-frequency support mode has ended, the value of the management target counter is “2”, and the current management target is the front door frame 14. In this case, it is determined whether the front door frame 14 is closed. When the opportunity to switch the output state of the signal corresponding to the value of the managed counter to the LOW level has occurred (step S1009: YES), the output state of the signal corresponding to the value of the managed counter is set to the LOW level ( Step S1010).

If a negative determination is made in step S1004, the processing of step S1006 is executed, a negative determination is made in step S1007, the processing of step S1008 is executed, a negative determination is made in step S1009, or When the process of S1010 is executed, the value of the managed counter of the main RAM 65 is decremented by 1 (step S1011). Then, it is determined whether or not the value of the managed counter after the subtraction of 1 is "0" (step S1012). When the value of the management target counter is 1 or more (step S1012: NO), the process from step S1002 is executed on the management target corresponding to the new management target counter value.

Next, the history setting process executed by the management-side CPU 112 will be described with reference to the flowchart of FIG. The history setting process is executed in step S908 of the management process (FIG. 23).

First, the number of buffers to be confirmed in the management CPU 112 among the first to fourteenth buffers 122a to 122n is set in the confirmation counter provided in the management RAM 114 (step S1101). Specifically, of the first to fourteenth correspondence areas 123a to 123n in the correspondence memory 116, the number of correspondence areas in which information other than the information indicating blank is stored is specified, and the identification is performed. The information of the number that was set is set in the check target counter. As described above, in the pachinko machine 10, since information other than the information indicating that it is blank is stored in the first to eleventh correspondence areas 123a to 123k, "11" is set in the confirmation target counter in step S1101. To do.

Then, it is confirmed whether or not the numerical information stored in the buffer corresponding to the current value of the check target counter among the first to fourteenth buffers 122a to 122n has been changed from "0" to "1". Then, it is determined whether or not the output state of the input signal from the main CPU 63 to the buffer has been switched from the LOW level to the HI level (step S1102). When the value of the check target counter is "n", the nth buffers 122a to 122n are the check targets of the numerical information. For example, if the value of the check target counter is "11", the eleventh buffer 122k is the check target of the numerical information, and if the value of the check target counter is "5", the fifth buffer 122e is the check target of the numerical information. ..

When an affirmative determination is made in step S1102, the RTC information that is the date information and the time information is read from the RTC 115 (step S1103). Then, the writing process to the history memory 117 is executed (step S1104). In the writing process, the pointer area 126 of the history memory 117 is referred to identify the pointer information of the history area 124 that is the current writing target, and the pointer information corresponding to the pointer information of the writing target is specified. The RTC information read in step S1103 is written in the history information storage area 125 of the history area 124. Also, the correspondence information is read from the correspondence areas 123a to 123n corresponding to the current value of the check target counter, and the correspondence information is written in the history information storage area 125 corresponding to the pointer information to be written. Further, when the correspondence information is any one of the information indicating the open/close execution mode, the information indicating the high frequency support mode, and the information indicating the front door frame 14, Not only the correspondence information but also the start information is written in the history information storage area 125 corresponding to the pointer information to be written. In addition, when the value of the check target counter is “n”, the n-th correspondence area 123a to 123n is a target for reading correspondence information. For example, if the value of the check target counter is “11”, the eleventh correspondence relationship area 123k is the target for reading the correspondence relationship information, and if the value of the check target counter is “5”, the fifth correspondence relationship area 123e is the correspondence relationship. It is a target for reading information.

By performing the writing process as described above, the value of the confirmation target counter is any one of the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first operating opening 33, the second operating opening 34, and the game times. In the case of, the RTC information, the outlet 24a, the general winning opening 31, the special prize winning device 32, the first working opening 33, and the second opening are stored in the history information storage area 125 corresponding to the pointer information to be written. A combination of the corresponding information indicating that the operation port 34 is one of the game times is stored as history information. When the value of the check target counter is one of the open/close execution mode, the high-frequency support mode, and the front door frame 14, the RTC information is stored in the history information storage area 125 corresponding to the pointer information to be written. The combination of the opening/closing execution mode, the high-frequency support mode, and the correspondence information indicating any one of the front door frames 14 and the start information is stored as history information.

Then, the update process of the target pointer is executed (step S1105). In the update processing, the numerical information stored in the pointer area 126 of the history memory 117 is read and 1 is added. It is determined whether or not the pointer information after the addition of 1 exceeds the maximum value of the pointer information in the history area 124. If the maximum value is not exceeded, the pointer information after adding 1 is overwritten in the pointer area 126 as new pointer information to be written. If the maximum value is exceeded, the pointer area 126 is cleared to "0" so that the pointer information to be written becomes the first pointer information.

If a negative determination is made in step S1102, or if the processing of step S1105 is executed, it is determined whether or not the signal output has been switched to the LOW level in the correspondence areas 123a to 123n corresponding to the current value of the check target counter. It is determined whether or not the correspondence information to be confirmed is stored (step S1106). Specifically, when the current value of the check target counter is "8" to "10", the corresponding correspondence areas 123h to 123j have the information indicating the open/close execution mode and the high frequency support mode. Since either the information indicating that there is the information or the information indicating that it is the front door frame 14 is stored, a positive determination is made in step S1106.

When an affirmative determination is made in step S1106, the numerical value information stored in the buffer corresponding to the current value of the check target counter among the first to fourteenth buffers 122a to 122n is changed from "1" to "0". By checking whether or not the output state of the input signal from the main CPU 63 to the buffer has been switched from the HI level to the LOW level (step S1107). If an affirmative decision is made in step S1107, the RTC information is read out (step S1108), as in step S1103, and writing processing to the history memory 117 is executed (step S1109). In the writing process, the RTC information read in step S1108 is written in the history information storage area 125 of the history area 124 corresponding to the pointer information that is the writing target. Also, the correspondence information is read from the correspondence areas 123a to 123n corresponding to the current value of the check target counter, and the correspondence information is written in the history information storage area 125 corresponding to the pointer information to be written. Further, not only the correspondence information but also the end information is written in the history information storage area 125 corresponding to the pointer information to be written. By executing the writing process in this way, when the value of the check target counter is one of the open/close execution mode, the high frequency support mode, and the front door frame 14, the pointer information corresponding to the write target is dealt with. In the history information storage area 125, a combination of RTC information, correspondence information indicating any one of the opening/closing execution mode, the high frequency support mode, and the front door frame 14, and the end information is stored as history information. It will be in the state of being. After that, similar to step S1105, the target pointer update processing is executed (step S1110).

If a negative determination is made in step S1106, a negative determination is made in step S1107, or if the process of step S1110 is executed, the value of the check target counter of the management side RAM 114 is decremented by 1 (step S1111). Then, it is determined whether or not the value of the check target counter after the subtraction of 1 is "0" (step S1112). When the value of the check target counter is 1 or more (step S1112: NO), the process from step S1102 is executed on the check target corresponding to the new check target counter value.

Next, how the history information is stored in the history memory 117 will be described with reference to the time chart of FIG. FIG. 27A shows a period in which a HI level signal is input to any of the first to seventh and eleventh buffers 122a to 122g, 122k, and FIG. 27B shows the HI level signal to the eighth buffer 122h. 27(c) shows a period in which the HI level signal is input to the ninth buffer 122i, and FIG. 27(d) shows a HI level signal in the tenth buffer 122j. 27(e) shows the timing of writing history information to the history memory 117.

At the timing of t1, the output state of the signal input to any of the first to seventh and eleventh buffers 122a to 122g, 122k is switched from the LOW level to the HI level as shown in FIG. Therefore, the history information is written in the history memory 117 at the timing of t1 as shown in FIG. After that, at the timing of t2, the signal switched to the HI level at the timing of t1 is switched to the LOW level as shown in FIG. However, the signal is a signal input to any of the first to seventh and eleventh buffers 122a to 122g and 122k, and the switching of the LOW level is not a target for storing history information. At the timing, writing of history information is not executed as shown in FIG.

Then, at each of the timing of t3, the timing of t5, the timing of t6, the timing of t9, the timing of t10, the timing of t13, and the timing of t14, as shown in FIG. The output state of the signal input to any of the 11 buffers 122a to 122g and 122k is switched from the LOW level to the HI level. Therefore, at each of these timings, the history information is written as shown in FIG.

As shown in FIG. 27B, the output state of the signal input to the eighth buffer 122h becomes the HI level from the timing of t4 to the timing of t7. The eighth buffer 122h corresponds to the presence/absence of the open/close execution mode. Therefore, as shown in FIG. 27E, the timing t4, which is the timing when the output state of the signal input to the eighth buffer 122h switches to the HI level, and the timing when the output state of the signal switches to the LOW level. The history information is written at each timing t7. In this case, the history information written at the timing of t4 includes start information, and the history information written at the timing of t7 includes end information. As a result, by checking the history information in the history memory 117, it is possible to grasp the execution period of the open/close execution mode.

Further, history information is written in the history memory 117 in the order of passage of time. Therefore, whether the history information indicating that a ball has entered the outlet 24a, the general winning opening 31, the special electric winning device 32, the first operating opening 33, or the second operating opening 34 is in the opening/closing execution mode. It becomes possible to distinguish whether or not. Further, since the history information includes RTC information, by comparing the RTC information, any of the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first working opening 33, and the second working opening 34 can be obtained. It is possible to distinguish whether or not the history information indicating that a ball has entered is in the opening/closing execution mode.

As shown in FIG. 27C, the output state of the signal input to the ninth buffer 122i becomes the HI level from the timing t8 to the timing t11. The ninth buffer 122i corresponds to the presence/absence of the high frequency support mode. Therefore, as shown in FIG. 27(e), the timing of t8 when the output state of the signal input to the ninth buffer 122i switches to the HI level and the timing when the output state of the signal switches to the LOW level. The history information is written at each timing t11. In this case, the history information written at the timing of t8 includes start information, and the history information written at the timing of t11 includes end information. As a result, by checking the history information in the history memory 117, the execution period of the high frequency support mode can be grasped.

Further, history information is written in the history memory 117 in the order of passage of time. Therefore, history information indicating that a ball has entered into any of the outlet 24a, the general winning opening 31, the special electric winning device 32, the first operating opening 33, and the second operating opening 34 is displayed even in the high-frequency support mode. It becomes possible to distinguish whether or not. Further, since the history information includes RTC information, by comparing the RTC information, any of the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first working opening 33, and the second working opening 34 can be obtained. It is possible to distinguish whether or not the history information indicating that a ball has entered the high frequency support mode is in the high frequency support mode.

As shown in FIG. 27D, the output state of the signal input to the tenth buffer 122j becomes the HI level from the timing of t12 to the timing of t15. The tenth buffer 122j corresponds to whether or not the front door frame 14 is opened. Therefore, as shown in FIG. 27E, the timing t12 when the output state of the signal input to the tenth buffer 122j switches to the HI level, and the timing when the output state of the signal switches to the LOW level. The history information is written at each timing of t15. In this case, the history information written at the timing of t12 includes start information, and the history information written at the timing of t15 includes end information. As a result, by confirming the history information in the history memory 117, it is possible to grasp the period during which the front door frame 14 is in the open state.

Further, history information is written in the history memory 117 in the order of passage of time. Therefore, history information indicating that a ball has entered into any of the outlet 24a, the general winning opening 31, the special electric winning device 32, the first operating opening 33, and the second operating opening 34 is opening the front door frame 14. It becomes possible to distinguish whether or not it is. Further, since the history information includes RTC information, by comparing the RTC information, any of the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first working opening 33, and the second working opening 34 can be obtained. It is possible to distinguish whether or not the history information indicating that a ball has entered the car is opening the front door frame 14.

Next, the output processing of the set value update signal executed when the setting state of the pachinko machine 10 is set by the main CPU 63 will be described. FIG. 28 is a flowchart showing the output processing of the set value update signal executed by the main CPU 63. The output process of the set value update signal is executed in step S119 in the main process (FIG. 9).

A value corresponding to the set value of the pachinko machine 10 set this time is set in the pulse number counter provided in the main RAM 65 (step S1201). Specifically, the value of the set value counter of the main RAM 65 is set in the pulse number counter. Then, it is determined whether or not the set value update signal directed to the management CPU 112 is at the HI level (step S1202). As described above, the set value update signal is input to the fifteenth buffer 122o of the input port 121 in the management IC 66. Here, the output processing of the set value update signal is processing for causing the management-side CPU 112 to specify the types of signals input to the first to fourteenth buffers 122a to 122n of the input port 121 in the main processing (FIG. 9). It is executed at a timing before a certain recognition process. On the other hand, the fact that the set value update signal is input to the fifteenth buffer 122o is set in the management IC 66 at the design stage of the pachinko machine 10. Therefore, the set value update signal is output before the recognition process. Even if the processing is executed, it becomes possible for the management side CPU 112 to specify that the signal input to the fifteenth buffer 122o is the set value update signal.

When a negative determination is made in step S1202, the value of the LOW level counter provided in the main RAM 65 is decremented by 1 (step S1203), and whether or not the value of the LOW level counter after the decrement is 1 is "0". It is determined whether or not (step S1204). The LOW level counter is a counter for the main CPU 63 to specify whether or not the set value update signal has been kept at the LOW level for a predetermined period while a plurality of pulses in which the set value update signal becomes the HI level is output. Is. When the value of the LOW level counter is “0” (step S1204: YES), it means that it is time to set the set value update signal to the HI level, so the set value update signal is set to the HI level. It is set (step S1205).

Then, "20" is set to the HI level counter provided in the main RAM 65 (step S1206). The HI level counter is a counter for the main CPU 63 to specify the period during which the set value update signal is maintained at the HI level. Since the value set in the HI level counter is decremented by 1 in a cycle of about 10 microseconds, the set value update signal is maintained at the HI level for 200 microseconds when one pulse is output. This HI level maintenance period is a period sufficient for the management side CPU 112 to specify that the set value update signal has been changed from the LOW level to the HI level.

When the set value update signal is at the HI level (step S1202: YES), the value of the HI level counter of the main RAM 65 is decremented by 1 (step S1207), and the value of the HI level counter after the decrement by 1 is set to "0". It is determined whether or not (step S1208). When the value of the HI level counter is “0” (step S1208: YES), it means that it is time to set the set value update signal to the LOW level, so the set value update signal is set to the LOW level. It is set (step S1209).

After that, the value of the pulse number counter of the main RAM 65 is decremented by 1 (step S1210), and it is determined whether the value of the pulse number counter after the decrement by 1 is "0" (step S1211). When the value of the pulse number counter is not “0” (step S1211: NO), the output of the pulse signal by the set value update signals for the number corresponding to the set value of the pachinko machine 10 set this time is completed. Since it means that there is not, "20" is set to the LOW level counter of the main RAM 65 (step S1212). Since the value set in the LOW level counter is decremented by 1 in a cycle of about 10 microseconds, the LOW level is maintained for 200 microseconds between a plurality of pulse outputs by the set value update signal. This LOW level maintenance period is a period sufficient for the management side CPU 112 to specify that the set value update signal has been changed from the HI level to the LOW level.

When the value of the pulse number counter is "0" (step S1211: YES), it means that the output of the pulse signals by the set value update signals for the number corresponding to the set value of the pachinko machine 10 set this time is completed. Therefore, the output processing of the setting value identification end command is executed (step S1213). The set value identification end command is a command for causing the management CPU 112 to recognize that the output of the set value update signal for causing the management CPU 112 to recognize the set value of the pachinko machine 10 set this time is completed. When outputting the set value identification end command, the first to eighth signals input to the first to eighth buffers 122a to 122h are used in the same manner as the identification start command, the type identification command, and the identification end command. However, the signal pattern of the set value identification end command is different from the identification start command, the type identification command, and the identification end command.

As described above, in the output processing of the set value update signal, the pulse signals of the set value update signals corresponding to the set value of the pachinko machine 10 set at the start of the supply of the operating power this time are output to the management IC 66. To do. The management side CPU 112 grasps the number of pulse signals by the set value update signal by executing the setting update recognition process, and grasps the set value of the pachinko machine 10 set this time based on it.

FIG. 29 is a flowchart showing the setting update recognition process executed by the management CPU 112. The setting update recognition process is executed in step S902 of the management process (FIG. 23).

It is determined whether or not the set value update signal input to the fifteenth buffer 122o of the input port 121 has switched from the LOW level to the HI level (step S1301). When an affirmative determination is made in step S1301, the value of the set value grasping counter provided in the management side RAM 114 is set to "1" (step S1302). The set value grasping counter is a counter for the management side CPU 112 to specify the set value of the pachinko machine 10. For example, if the value of the set value grasping counter is "1", it means "setting 1", If the value of the setting value grasping counter is "6", it means "setting 6".

After that, it is determined whether or not the set value update signal input to the fifteenth buffer 122o of the input port 121 has switched from the LOW level to the HI level again (step S1303). If an affirmative decision is made in step S1303, the value of the set value grasping counter of the management side RAM 114 is incremented by 1 (step S1304). As a result, the set value of the pachinko machine 10 specified by the management-side CPU 112 is increased by one step.

If a negative determination is made in step S1303, or if the process of step S1304 is executed, based on the input state of the first to eighth signals input to the first to eighth buffers 122a to 122h of the input port 121. Then, it is determined whether or not a setting value identification end command has been received from the main CPU 63 (step S1305). When a negative determination is made in step S1305, the process returns to step S1303.

When an affirmative determination is made in step S1305, the RTC information that is the date information and the time information is read from the RTC 115 (step S1306). Then, the writing process to the history memory 117 is executed (step S1307). In the writing process, the pointer area 126 of the history memory 117 is referred to identify the pointer information of the history area 124 that is the current writing target, and the pointer information corresponding to the pointer information of the writing target is specified. The RTC information read in step S1306 is written in the history information storage area 125 of the history area 124. Further, both the information for identifying the set value and the value information of the set value grasping counter are written in the history information storage area 125 corresponding to the pointer information to be written. Thereby, the information indicating that the setting state of the pachinko machine 10 is newly set, the RTC information corresponding to the date and time when the setting is performed, and the information of the setting value when the setting is performed, The combination is stored as history information.

After that, the update processing of the target pointer is executed (step S1308). In the update processing, the numerical information stored in the pointer area 126 of the history memory 117 is read and 1 is added. It is determined whether or not the pointer information after the addition of 1 exceeds the maximum value of the pointer information in the history area 124. If the maximum value is not exceeded, the pointer information after adding 1 is overwritten in the pointer area 126 as new pointer information to be written. If the maximum value is exceeded, the pointer area 126 is cleared to "0" so that the pointer information to be written becomes the first pointer information.

When the setting state of the pachinko machine 10 is newly set by performing the setting update recognition process as described above, the setting is performed, the date and time when the setting is performed, and the setting date and time. A combination of set values when the setting is performed is stored in the history area 124 as history information. As a result, the date and time when the setting state of the pachinko machine 10 is newly set and the setting is performed by reading and analyzing the information stored in the history memory 117 by using the external device connected to the reading terminal 68d. It becomes possible to grasp the contents of the set value when the setting is performed.

Here, even if the setting state of the pachinko machine 10 is newly set, the information stored in the history memory 117 is maintained as it is. As a result, even if the setting state of the pachinko machine 10 is newly set, it is possible to prevent the history information in the history memory 117 from being deleted, and various parameters to be described later are the timing of changing the setting state of the pachinko machine 10. It is calculated by using the history information existing before and after. In this case, since the date and time when the setting state of the pachinko machine 10 is newly set is stored in the history memory 117 as described above, it is stored in the history memory 117 by connecting an external device to the reading terminal 68d. By reading the information, it becomes possible to calculate various parameters after the timing when the setting state of the pachinko machine 10 is newly set and during the period when the setting state is maintained.

Next, the display output processing executed by the management CPU 112 will be described with reference to the flowchart of FIG. The display output process is executed in step S909 of the management process (FIG. 23).

First, it is determined whether it is the calculation timing (step S1401). If 51 seconds have elapsed since the supply of operating power to the management-side CPU 112 was started, or if 51 seconds have elapsed since the positive determination was made in step S1401 last time, an affirmative determination is made in step S1401. When an affirmative determination is made in step S1401, various numbers of normally entered balls are calculated (step S1402). Specifically, first, by counting the number of history information storage areas 125 in the history area 124 of the history memory 117 in which the correspondence information indicating the outlets 24a is stored, Calculate the number of incoming balls. In addition, by counting the number of history information storage areas 125 in which the correspondence information indicating the general winning opening 31 is stored in the history area 124 of the history memory 117, the entry into the general winning opening 31 is achieved. Calculate the number. In addition, by counting the number of history information storage areas 125 in which the corresponding relationship information indicating the special electric prize winning device 32 is stored in the history area 124 of the history memory 117, the special electric prize winning device 32 is entered. Calculate the number. In addition, by counting the number of history information storage areas 125 in which the corresponding relationship information indicating the first operating ports 33 is stored in the history area 124 of the history memory 117, the first operating ports 33 are stored. Calculate the number of incoming balls. In addition, by counting the number of history information storage areas 125 in the history area 124 of the history memory 117 in which the corresponding relationship information indicating the second operation ports 34 is stored, Calculate the number of incoming balls.

After that, in the history area 124 of the history memory 117, the history information storage area 125 in which the correspondence information indicating the front door frame 14 and the start information are stored, and the correspondence relationship indicating the front door frame 14 are stored. By referring to the history information storage area 125 existing in the period between the history information storage area 125 in which the information and the end information are stored, the exit port generated in the situation where the front door frame 14 is in the open state 24a, the general winning opening 31, the special electric winning device 32, the first working opening 33, and the second working opening 34, respectively, the number of balls entered is calculated (step S1403). In the history area 124 of the history memory 117, the history information storage area 125 in which the correspondence information indicating the front door frame 14 and the start information are stored, and the correspondence information indicating the front door frame 14 and The period between the end information and the history information storage area 125 is calculated from the RTC information stored in the history information storage area 125. In addition, in the entire pointer information that is the serial number, the history information storage area 125 in which the correspondence information indicating the front door frame 14 and the start information are stored, and the correspondence relation indicating the front door frame 14 are stored. When there are a plurality of sections with the history information storage area 125 in which the information and the end information are stored, the total number of incoming balls for the section is calculated. Further, although there is the history information storage area 125 in which the correspondence information indicating the front door frame 14 and the start information are stored, the RTC information corresponding to the time after the history information storage area 125 is present. If the correspondence information and the end information indicating the front door frame 14 are not stored in the history information storage area 125 in which is stored, the correspondence information and the start information indicating the front door frame 14 are stored. The history information in the history information storage area 125 in which RTC information corresponding to a time later than the history information storage area 125 is stored is treated as when the front door frame 14 is in the open state.

Then, various parameters are calculated using the calculation results of steps S1402 and S1403 (step S1404). Specifically, first, the number of incoming balls generated during the opening of the front door frame 14 calculated in step S1403 is subtracted from each number of incoming balls calculated in step S1402. Then, the following first to eighth parameters are calculated using the respective numbers of incoming balls after the subtraction. The difference between the number of balls entered into the outlet 24a calculated in step S1402 and the number of balls entered into the outlet 24a calculated in step S1403 is defined as the number of entered balls K1, and the number of the general winning openings 31 calculated in step S1402 is calculated. The difference in the number of balls of the general winning opening 31 calculated in step S1403 with respect to the number of balls is defined as the number of balls entered K2, and the special electric prize winning device calculated in step S1403 with respect to the number of balls of the special electric prize winning device 32 calculated in step S1402. The difference in the number of entered balls in 32 is K3, and the difference in the number of entered balls in the first operating port 33 calculated in step S1403 with respect to the number of entered balls in the first operating port 33 calculated in step S1402 The number K4 is defined as the number K4, and the difference between the number of balls entered in the second operation port 34 calculated in step S1402 and the number of balls entered in the second operation port 34 is set as number K5.
First parameter: total payout number of game balls (K2 x "number of prize balls for winning in general prize hole 31" + K3 x "number of prize balls for winning in special electric prize winning device 32" + K4 x "first working port 33" Ratio of the number of prize balls for winning the prize"+K5 x "Number of prize balls for winning the second operating port 34")/total number of game balls discharged from the game area PA (K1+K2+K3+K4+K5) (hereinafter, this ratio is "D1")
-Second parameter: ratio of the total number K2 of game balls to the general winning opening 31 / the total number (K1+K2+K3+K4+K5) of game balls discharged from the game area PA-Third parameter: game balls to the special prize winning device 32 Ratio of the total number of entered balls K3/the total number of game balls discharged from the game area PA (K1+K2+K3+K4+K5) The fourth parameter: The total number of entered balls K4 into the first working opening 33/discharged from the game area PA Ratio of the total number of game balls played (K1+K2+K3+K4+K5) (hereinafter, this ratio is referred to as “D2”)
-Fifth parameter: ratio of the total number of game balls K5 entering the second operating port 34 / the total number of game balls discharged from the game area PA (K1 + K2 + K3 + K4 + K5) (hereinafter, this ratio is referred to as "D3")
-Sixth parameter: D1-(D2 x "number of prize balls for winning in the first operating port 33" + D3 x "number of prize balls for winning in the second operating port 34")
-Seventh parameter: (K3 x "number of prize balls for winning in special electric prize winning device 32" + K5 x "number of prize balls for winning in second working port 34")/total payout number of game balls (K2 x "general “Number of prize balls for winning in prize hole 31”+K3דNumber of prize balls for winning in special electric prize winning device 32”+K4דNumber of prize balls for prize in first operating port 33”+K5דSecond operating port 34” 8th parameter: K3 x "number of prize balls for winning in special electric prize winning device 32"/total number of game balls paid out (K2 x "for winning in general winning hole 31") "Number of prize balls" + K3 x "Number of prize balls for winning the special electric prize winning device 32" + K4 x "Number of prize balls for winning the first operating port 33" + K5 x "Number of prize balls for winning the second operating port 34" )) In step S1404, the first to eighth parameters, which are the calculation results, are stored in the normal time storage area in the calculation result memory 131. The first to eighth parameters stored in the normal time storage area are stored and held until the next step S1404 is executed. That is, when the next step S1404 is executed and the first to eighth parameters are calculated, the newly calculated first to eighth parameters are stored in the normal time storage area, The previous calculation results of the first to eighth parameters stored in the normal-time storage area are overwritten.

Thereafter, in the history area 124 of the history memory 117, the history information storage area 125 in which the correspondence information indicating the open/close execution mode and the start information are stored, and the correspondence information indicating the open/close execution mode and By referring to the history information storage area 125 existing in the period between the end information and the history information storage area 125, the outlet 24a and the general winning opening 31 generated in the open/close execution mode are referred to. , The special electric prize winning device 32, the first actuating port 33 and the second actuating port 34, respectively, the number of incoming balls is calculated (step S1405). A history information storage area 125 in which correspondence information indicating the open/close execution mode and start information are stored in the history area 124 of the history memory 117, and correspondence information and end information indicating the open/close execution mode. Is calculated from the RTC information stored in the history information storage area 125. Further, in the entire pointer information that is a serial number, the history information storage area 125 in which the correspondence information indicating the open/close execution mode and the start information are stored, and the correspondence information indicating the open/close execution mode and When there are a plurality of sections with the history information storage area 125 in which the end information is stored, the total number of incoming balls for the total of the sections is calculated. Further, although the history information storage area 125 in which the correspondence information indicating the open/close execution mode and the start information are stored exists, the RTC information corresponding to a time later than the history information storage area 125 is stored. When the stored history information storage area 125 does not store the correspondence information indicating the open/close execution mode and the end information, the correspondence information indicating the open/close execution mode and the start information are stored. All history information in the history information storage area 125 in which RTC information corresponding to a time later than the history information storage area 125 is stored is treated as in the open/close execution mode.

After that, during the period of the open/close execution mode specified in step S1405, the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first working opening 33, and the like generated in the situation where the front door frame 14 is in the open state. The number of balls entering each of the second working ports 34 is calculated (step S1406). The method of calculating the number of entered balls is the same as that in step S1403, except that the period of the opening/closing execution mode specified in step S1405 is assumed.

Then, various parameters are calculated using the calculation results of step S1405 and step S1406 (step S1407). Specifically, first, the number of incoming balls generated during opening of the front door frame 14 calculated in step S1406 is subtracted from the number of incoming balls calculated in step S1405. Then, the following eleventh to eighteenth parameters are calculated by using the respective numbers of incoming balls after the subtraction. In addition, the difference between the number of entered balls of the outlet 24a calculated in step S1406 and the number of entered balls of the outlet 24a calculated in step S1405 is defined as the number of entered balls K11, and the winning of the general winning opening 31 calculated in step S1405. The difference in the number of balls of the general winning opening 31 calculated in step S1406 with respect to the number of balls is defined as the number of balls entered K12, and the special prize winning device calculated in step S1406 with respect to the number of balls of the special prize device 32 calculated in step S1405 The difference in the number of entered balls of 32 is defined as the number of entered balls K13, and the difference in the number of entered balls of the first operating port 33 calculated in step S1406 with respect to the number of entered balls of the first operating port 33 calculated in step S1405 is entered. The number K14 is defined as the number K14, and the difference between the number of balls entered in the second operation port 34 calculated in step S1405 and the number of balls entered in the second operation port 34 is set as number K15.
Eleventh parameter: total payout number of game balls (K12 x "number of prize balls for winning in general prize hole 31" + K13 x "number of prize balls for winning in special electric prize winning device 32" + K14 x "first operating port 33" Ratio of the number of prize balls for winning the prize”+K15דthe number of prize balls for winning the second operating port 34”)/the total number of the game balls discharged from the game area PA (K11+K12+K13+K14+K15) (hereinafter, this ratio is “ D11")
・Twelfth parameter: ratio of the total number of game balls K12 into the general winning opening 31/the total number of game balls (K11+K12+K13+K14+K15) discharged from the game area PA. ・Thirteenth parameter: Game balls to the special electric prize winning device 32. Ratio of the total number of entered balls K13/the total number of game balls discharged from the game area PA (K11+K12+K13+K14+K15)・Fourteenth parameter: The total number of entered balls K14 into the first operation port 33/discharged from the game area PA Ratio of the total number of game balls played (K11+K12+K13+K14+K15) (hereinafter, this ratio is referred to as “D12”)
Fifteenth parameter: the ratio of the total number of game balls K15 entering the second operation port 34/the total number of game balls discharged from the game area PA (K11+K12+K13+K14+K15) (hereinafter, this ratio is referred to as “D13”)
-Sixteenth parameter: D11-(D12 x "number of prize balls for winning in first operating port 33" + D13 x "number of prize balls for winning in second operating port 34")
17th parameter: (K13 x "number of prize balls for winning in special electric prize winning device 32" + K15 x "number of prize balls for winning in second working port 34")/total payout number of game balls (K12 x "general "Number of prize balls for winning in prize hole 31" + K13 x "Number of prize balls for winning in special electric prize winning device 32" + K14 x "Number of prize balls for prize in first operating port 33" + K15 x "Second operating port 34" 18th parameter: K13 x "number of prize balls for winning in special electric prize winning device 32"/total payout number of game balls (K12 x for winning in general winning hole 31) "Number of prize balls" + K13 x "Number of prize balls for winning the special electric prize winning device 32" + K14 x "Number of prize balls for winning the first operating port 33" + K15 x "Number of prize balls for winning the second operating port 34" )) in step S1407, the 11th to 18th parameters, which are the calculation results, are stored in the storage area for the open/close execution mode in the calculation result memory 131. The 11th to 18th parameters stored in the storage area for opening/closing execution mode are stored and held until the next step S1407 is executed. That is, when the next step S1407 is executed and the first to eighteenth parameters are calculated, the newly calculated first to eighteenth parameters are stored in the storage area for opening/closing execution mode. The previous calculation results of the 11th to 18th parameters stored in the storage area for the opening/closing execution mode are overwritten.

Then, in the history area 124 of the history memory 117, the history information storage area 125 in which the correspondence information indicating the high frequency support mode and the start information are stored, and the correspondence relationship indicating the high frequency support mode. By referring to the history information storage area 125 existing in a period between the history information storage area 125 in which the information and the end information are stored, the outlet 24a generated in the high frequency support mode, The number of winning balls to each of the winning opening 31, the special electric winning device 32, the first operating opening 33 and the second operating opening 34 is calculated (step S1408). In the history area 124 of the history memory 117, the history information storage area 125 in which the correspondence information indicating the high frequency support mode and the start information are stored, and the correspondence information indicating the high frequency support mode and The period between the end information and the history information storage area 125 is calculated from the RTC information stored in the history information storage area 125. Further, in the entire pointer information that is a serial number, the history information storage area 125 in which the correspondence information indicating the high frequency support mode and the start information are stored, and the correspondence relation indicating the high frequency support mode. When there are a plurality of sections with the history information storage area 125 in which the information and the end information are stored, the total number of incoming balls for the section is calculated. Further, although there is the history information storage area 125 in which the correspondence information indicating the high frequency support mode and the start information are stored, the RTC information corresponding to the time after the history information storage area 125 is present. If the correspondence information and the end information indicating the high frequency support mode are not stored in the history information storage area 125 in which is stored, the correspondence information and the start information indicating the high frequency support mode are stored. All history information in the history information storage area 125 in which RTC information corresponding to a time later than the history information storage area 125 is stored is treated as in the high-frequency support mode.

After that, during the period of the high-frequency support mode specified in step S1408, the outlet 24a, the general winning opening 31, the special prize winning device 32, and the first operating opening 33 that are generated when the front door frame 14 is in the open state. Then, the number of balls entering each of the second operation ports 34 is calculated (step S1409). The method of calculating the number of entered balls is the same as that in step S1403, except that the period of the high-frequency support mode specified in step S1408 is assumed.

Then, various parameters are calculated using the calculation results of steps S1408 and S1409 (step S1410). Specifically, first, the number of incoming balls generated during the opening of the front door frame 14 calculated in step S1409 is subtracted from each number of incoming balls calculated in step S1408. Then, the following 21st to 26th parameters are calculated using the respective numbers of incoming balls after the subtraction. The difference in the number of balls entered into the outlet 24a calculated in step S1409 with respect to the number of balls entered into the outlet 24a calculated in step S1408 is defined as the number of entered balls K21, and the number of the general winning openings 31 calculated in step S1408 is calculated. The difference in the number of balls of the general winning opening 31 calculated in step S1409 with respect to the number of balls is defined as the number of balls entered K22, and the special prize winning device calculated in step S1409 with respect to the number of balls of the special prize winning device 32 calculated in step S1408 The difference in the number of entered balls of 32 is K23, and the difference in the number of entered balls of the first operating port 33 calculated in step S1409 with respect to the number of entered balls of the first operating port 33 calculated in step S1408 is entered. The number K24 is defined as the number K24, and the difference between the number of balls entered in the second operation port 34 calculated in step S1408 and the number of balls entered in the second operation port 34 is set as number K25.
21st parameter: total payout number of game balls (K22 x "number of prize balls for winning in general prize hole 31" + K23 x "number of prize balls for winning in special electric prize winning device 32" + K24 x "first operating port 33" The ratio of the total number of game balls discharged from the game area PA (K21+K22+K23+K24+K25) (hereinafter, this ratio is referred to as “the number of prize balls for winning the prize”+K25דthe number of prize balls for winning the second operating port 34”) D11")
-Twenty-second parameter: ratio of total number of game balls K22 to the general winning opening 31 / total number of game balls (K21+K22+K23+K24+K25) discharged from the game area PA-Twenty-third parameter: game ball to special prize winning device 32 Ratio of the total number of entered balls K23/the total number of game balls (K21+K22+K23+K24+K25) discharged from the game area PA. The 24th parameter: the total number of entered game balls K24 into the first working port 33/discharged from the game area PA. Ratio of the total number of game balls played (K21+K22+K23+K24+K25) (hereinafter, this ratio is referred to as “D22”)
25th parameter: ratio of the total number of game balls K25 entering the second operation port 34/the total number of game balls discharged from the game area PA (K21+K22+K23+K24+K25) (hereinafter, this ratio is referred to as “D23”)
-Twenty-sixth parameter: D21-(D22 x "number of prize balls for winning in first operating port 33" + D23 x "number of prize balls for winning in second operating port 34")
In step S1410, the 21st to 26th parameters, which are the calculation results, are stored in the storage area for high frequency support mode in the calculation result memory 131. The 21st to 26th parameters stored in the high-frequency support mode storage area are stored and held until the next step S1410 is executed. That is, when the next step S1410 is executed and the 21st to 26th parameters are calculated, the newly calculated 21st to 26th parameters are stored in the high-frequency support mode storage area. Then, the previous calculation results of the 21st to 26th parameters stored in the storage area for the high frequency support mode are overwritten.

Then, the frequency of occurrence of the open/close execution mode is calculated and stored (step S1411). Specifically, in the history area 124 of the history memory 117, by counting the number of history information storage areas 125 in which the correspondence information and the start information indicating the opening/closing execution mode are stored, the opening/closing execution mode is calculated. Calculate the number of occurrences of. Further, the number of times the game times have occurred is calculated by counting the number of history information storage areas 125 in which the correspondence information indicating that the game times have started is stored in the history area 117 of the history memory 117. .. Then, the number of times the open/close execution mode is generated per unit game time is calculated. The number of times the open/close execution mode is generated is K31, and the number of game times is K32.
・Thirty-first parameter: K31/K32
In step S1411, the 31st parameter which is the calculation result is stored in the storage area for opening/closing execution mode frequency in the calculation result memory 131. The 31st parameter stored in the storage area for opening/closing execution mode frequency is stored and held until the next step S1411 is executed. That is, when the next step S1411 is executed and the 31st parameter is calculated, the newly calculated 31st parameter is stored in the opening/closing execution mode frequency storage area, so that the opening/closing execution mode until then. The previous calculation result of the 31st parameter stored in the frequency storage area is overwritten.

Then, the frequency of occurrence of the high frequency support mode is calculated and stored (step S1412). Specifically, by counting the number of history information storage areas 125 in which the correspondence information indicating the high frequency support mode and the start information are stored in the history area 124 of the history memory 117, the high frequency Calculate the number of occurrences of support mode. Further, the number of times the game times have occurred is calculated by counting the number of history information storage areas 125 in which the correspondence information indicating that the game times have started is stored in the history area 117 of the history memory 117. .. Then, the number of occurrences of the high frequency support mode per unit game time, and the ratio of the number of occurrences of the high frequency support mode to the number of occurrences of the open/close execution mode are calculated. The number of times the high frequency support mode is generated is K41, the number of times the game is played is K42, and the number of times the open/close execution mode is calculated in step S1411 is K43.
41st parameter: K41/K42
42nd parameter: K41/K43
In step S1412, the 41st to 42nd parameters that are the calculation results are stored in the high-frequency support mode frequency storage area in the calculation result memory 131. The 41st to 42nd parameters stored in the high-frequency support mode frequency storage area are stored and held until the next step S1412 is executed. That is, when the next step S1412 is executed and the 41st to 42nd parameters are calculated, the newly calculated 41st to 42nd parameters are stored in the high-frequency support mode frequency storage area. Then, the previous calculation results of the 41st to 42nd parameters stored in the storage area for high frequency support mode frequency are overwritten.

When a negative determination is made in step S1401 or when the processing of step S1412 is executed, the display processing is executed (step S1413). FIG. 31 is a flowchart showing the display process.

First, the value of the update timing counter provided in the management side RAM 114 is decremented by 1 (step S1501). The update timing counter is a counter for the management-side CPU 112 to specify that it is the time to update the display content of the management result of the game history on the first to third notification display devices 69a to 69c. The management-side CPU 112 controls the display of the first to third notification display devices 69a to 69c, so that the first to eighth parameters, the first to eighteenth parameters, the twenty-first to twenty-sixth parameters, and the thirty-first parameters. The parameters and the calculation results of the 41st to 42nd parameters are reported. In this case, the first notification display device 69a displays information corresponding to the type of parameter to be notified. Further, among the values obtained by multiplying the parameter to be notified by 100, the numeral corresponding to the tens digit is displayed on the second notification display device 69b, and the numeral corresponding to the ones digit is displayed for the third notification. It is displayed on the device 69c. And in the 1st-3rd notification display devices 69a-69c, the said 1st-8th parameters, the said 11th-18th parameters, the said 21st-26th parameters, the said 31st parameters, and the said 41st-. The display corresponding to the calculation result of the 42nd parameter is sequentially switched according to a predetermined order, and after the calculation result of the 42nd parameter, which is the display object in the last order, is displayed, the display object in the first order is displayed. The calculation result of one parameter is displayed. In this case, the period during which the calculation result of one parameter is continuously displayed is 2 seconds.

Here, the calculation cycle of the various parameters in the management side CPU 112 is 51 seconds. On the other hand, the number of various parameters is 25, and the period during which the calculation result of one parameter is continuously displayed is 2 seconds. Therefore, the various parameters calculated by the management CPU 112 are displayed at least once on the first to third notification display devices 69a to 69c.

When the process of step S1501 is executed, the display contents of the first to third notification display devices 69a to 69c are updated by determining whether the value of the update timing counter after subtracting 1 is "0". It is determined whether or not it is the timing (step S1502). When an affirmative determination is made in step S1502, the value of the display target counter provided in the management-side RAM 114 is incremented by 1 (step S1503). When the value of the display target counter after adding 1 exceeds the maximum value of "24" (step S1504: YES), the value of the display target counter is cleared to "0" (step S1505).

The display target counter is a counter for the management-side CPU 112 to specify the type of parameter to be displayed on the first to third notification display devices 69a to 69c. Of the first to eighth parameters, the first to eighteenth parameters, the twenty-first to twenty-sixth parameters, the thirty-first parameters and the fourteenth to forty-second parameters, and the display target counter of "0" to "24". There is a one-to-one correspondence with the possible values. For example, when the value of the display target counter is "0", the first parameter, which is the first display target, becomes the display target of the first to third notification display devices 69a to 69c, and the value of the display target counter is "24". In the case of, the 42nd parameter, which is the last display target, becomes the display target of the first to third notification display devices 69a to 69c.

If a negative determination is made in step S1504, or if the process of step S1505 is executed, the first notification display device 69a is displayed so that information corresponding to the type of parameter corresponding to the value of the display target counter is displayed. It is controlled (step S1506). Further, the parameter corresponding to the value of the display target counter is read from the calculation result memory 131, the read parameter is multiplied by 100, and the numeral corresponding to the tens digit is displayed on the second notification display device 69b. The number corresponding to the ones digit is displayed on the third notification display device 69c (step S1507). The contents displayed on the first to third notification display devices 69a to 69c in step S1506 and step S1507 are continued until the next update timing or until the supply of operating power to the management-side CPU 112 is stopped. It After that, a value corresponding to 2 seconds is set as a value corresponding to the next update timing in the update timing counter of the management side RAM 114 (step S1508).

When the supply of operating power to the management-side CPU 112 is started by executing the display processing as described above, the game history management results are displayed on the first to third notification display devices 69a to 69c. To be done. The management result of the game history is displayed regardless of whether the game is continued or not, and the main body of the gaming machine 12 is opened with respect to the outer frame 11 so that the main controller 60 is operated from the front of the pachinko machine 10. It is performed regardless of whether it is visible. In this way, the display control of the first to third notification display devices 69a to 69c is executed irrespective of the status of the game and the state of the pachinko machine 10, so that the first to third notification display device 69a. It is possible to simplify the processing configuration for controlling the display of ~69c.

The display of the management result of the game history on the first to third notification display devices 69a to 69c is started after the supply of the operating power to the management CPU 112 is started and after the identification end command is received from the main CPU 63. To be done. In this case, like the information stored in the history memory 117, the information stored in the calculation result memory 131 is stored and retained even when the supply of operating power to the pachinko machine 10 is stopped. Therefore, when the supply of the operating power to the management-side CPU 112 is started, the management result of the game history calculated before the supply of the operating power to the management-side CPU 112 is stopped is displayed.

When the setting state of the pachinko machine 10 is set when the supply of the operating power to the main CPU 63 is started, information corresponding to the set value being changed is displayed on the third notification display device 69c. However, while the display of the information corresponding to the set value is performed before the identification end command is transmitted from the main CPU 63, the game history on the first to third notification display devices 69a to 69c. The display of the management result of is started after the identification end command is transmitted from the main CPU 63. Accordingly, even if the third notification display device 69c is also used as a display device for displaying information corresponding to the set value and displaying the management result of the game history, these displays are displayed. It is possible to prevent the periods from overlapping.

When the information corresponding to the set value is displayed, the first notification display device 69a and the second notification display device 69b are hidden. On the other hand, when the game history management result is displayed, the first notification display device 69a and the second notification display device 69b are not hidden. This makes it possible to identify which of the display of information corresponding to the set value and the display of the game history management result is being performed on the third notification display device 69c.

Next, regarding the processing configuration for outputting the history information stored in the history memory 117 and various parameters stored in the calculation result memory 131 to the external device electrically connected to the reading terminal 68d of the MPU 62 explain. FIG. 32A is a flowchart showing the data output process executed by the main CPU 63. The data output process is executed in step S112 in the main process (FIG. 9).

In the data output process, first, it is determined whether or not the connection signal indicating that the external device is electrically connected to the reading terminal 68d is received from the reading terminal 68d (step S1601). When a negative determination is made in step S1601, this data output process is ended as it is. In this case, in order to execute the data output process, it is necessary to restart the supply of operating power to the main CPU 63. As a result, in order to output the history information and various parameters to the outside, the supply of operating power to the main CPU 63 is started with the external device electrically connected to the reading terminal 68d. Need to Since the power switch for stopping and starting the supply of operating power to the main CPU 63 is provided in the payout mechanism unit 73 mounted on the back surface of the back pack unit 15, these stopping and starting operations are performed. In order to do so, it is necessary to open the gaming machine main body 12 with respect to the outer frame 11 to expose the back surface of the back pack unit 15. Under such circumstances, in order to output the history information and various parameters to the outside, the supply of the operating power to the main CPU 63 is started with the external device electrically connected to the reading terminal 68d. With the configuration that needs to be performed, it becomes possible to make it difficult to perform the operation of reading the history information and various parameters even if a person other than the game hall manager performs the operation.

When an affirmative determination is made in step S1601, it is determined whether or not a signal for confirming control information is received from the reading terminal 68d, so that the current connection of the external device to the reading terminal 68d is the main ROM 64. It is determined whether or not the control information (program and data) is checked (step S1602). The external device has a configuration that allows both confirmation of control information and confirmation of history information and various parameters.When confirmation of control information is selected by manual operation on the external device, the external device can confirm the control information. A signal for control information confirmation is transmitted, and when confirmation of history information and various parameters is selected by manual operation on the external device, a signal for history confirmation is transmitted from the external device. However, the configuration is not limited to this, and the control information confirmation external device and the history confirmation external device may be separate. In this case, when an external device for checking control information is electrically connected to the reading terminal 68d, a signal for checking control information is transmitted from the external device, and an external device for checking history is sent to the reading terminal 68d. When the device is electrically connected, a signal for history confirmation is transmitted from the external device.

If an affirmative decision is made in step S1602, an output process for confirming control information is executed (step S1603). In the output process, a program and data are read from the main ROM 64 as control information, and the read control information is output to the reading terminal 68d. As a result, the control information can be read by the external device electrically connected to the reading terminal 68d, and it can be confirmed whether the control information is regular or normal. Will be possible.

When a negative determination is made in step S1602, an output instruction signal is transmitted to the management side CPU 112 (step S1604). Specifically, the output state of the output instruction signal is switched from LOW level to HI level. This HI level output state is continued for a specific period. The specific period is a period sufficient for the management-side CPU 112 to specify that the HI level output instruction signal is input to the sixteenth buffer 122p. When the output state of the output instruction signal is switched to the HI level, the management side CPU 112 executes the process for outputting the history information.

Specifically, when the management-side CPU 112 switches the output state of the output instruction signal input to the sixteenth buffer 122p of the input port 121 from the LOW level to the HI level, as shown in the flowchart of FIG. (Step S1701: YES), the history information stored in the history memory 117 and various parameters stored in the operation result memory 131 are read out, and the read history information and various parameters are output to the reading terminal 68d. (Step S1702). As a result, the history information and various parameters can be read by the external device electrically connected to the reading terminal 68d, and the information on the management result of the game history can be analyzed. When the management-side CPU 112 outputs the history information to the reading terminal 68d, the management-side CPU 112 clears the history memory 117 by "0" (step S1703). The history information in the history memory 117 is deleted only when the history information is read by the external device.

Returning to the description of the data output process (FIG. 32A), when the process of step S1603 is performed or when the process of step S1604 is performed, the electrical connection of the external device to the reading terminal 68d is continued. It is determined whether it has been done (step S1605). If it is continued (step S1605: YES), the process stands by in step S1605. As a result, it is possible to prevent the processing set in the execution order after the data output processing from being executed until the external device is disconnected from the reading terminal 68d. When the connection of the external device to the reading terminal 68d is released (step S1605: NO), this data output process ends.

According to this embodiment described in detail above, the following excellent effects are exhibited.

Since the game ball is paid out when the game ball enters any of the general winning opening 31, the special electric winning device 32, the first operating opening 33, and the second operating opening 34, the player can select one of these entering portions. A game will be played while expecting a game ball to enter. In this configuration, the game ball enters the any of the outlet 24a, the general winning opening 31, the special electric winning device 32, the first operating opening 33, and the second operating opening 34 (hereinafter, also referred to as a history target entering portion). If the occurrence occurs, the history information corresponding to it will be stored in the history memory 117 of the management IC 66. As a result, the pachinko machine 10 can store and hold information for managing the number of game balls or the frequency of entering the game balls into each history target ball entering unit, and use this managed information. As a result, it becomes possible to appropriately manage the entry mode of the game ball into each history target entry part. Further, since the history information is stored and held by the pachinko machine 10 itself, it becomes possible to prevent unauthorized access to the history information and unauthorized modification.

All the ball-in units for ejecting the game balls from the game area PA are targets for execution of the history information storage process and targets for management using the history information. As a result, it becomes possible to manage the ball entry frequency for any history-target ball entry section by using the history information. In addition, it is possible to manage the ratio of the number of game balls entering each history target ball portion to the number of game balls discharged from the game area PA using history information.

The history information includes RTC information, which is information corresponding to the timing at which the game ball enters the history-targeted ball entering section that has triggered the storage of the history information. With this, by using the history information, it is possible to grasp the entry history of the game ball into the history entry ball portion in detail.

In the memory 117 for history, not only history information corresponding to the game ball entering the history target ball-entering section, but also history information indicating whether or not the opening/closing execution mode is in effect, and the high-frequency support mode is in effect. The history information indicating whether or not and the history information indicating whether or not the front door frame 14 is open are stored. As a result, it is possible to manage whether or not the game sphere enters the history target ball-in part by distinguishing whether or not each of these situations is present.

It is possible to output the history information stored in the history memory 117 to an external device which is a device outside the pachinko machine 10. This makes it possible to read history information with an external device and use the read history information to analyze the ball entry mode of the game ball into the history target ball entry section.

The MPU 62 is provided with a reading terminal 68d, and the program can be read from the main ROM 64 by an external device electrically connected to the reading terminal 68d. This makes it possible to confirm whether or not the program is normal. In this configuration, the history information stored in the history memory 117 is externally output using the reading terminal 68d for externally outputting the program. This makes it possible to output history information to the outside while preventing the configuration from becoming complicated.

The information to be output from the reading terminal 68d is specified as a program or history information, and the information on the side corresponding to the specification result is externally output through the reading terminal 68d. As a result, in the configuration in which the history information is externally output using the reading terminal 68d for externally outputting the program, it is determined whether the information to be externally output is the program or the history information. It is specified on the side, and the specified information is output to the outside. Therefore, it is possible to read only the necessary information even if the reading terminal 68d is also used.

Based on the information received from the external device electrically connected to the reading terminal 68d, it is specified whether the information to be output from the reading terminal 68d is the program or the history information. This makes it possible to prevent the configuration related to the selection of information to be output to the outside from becoming complicated.

An MPU 62 having a main ROM 64 that stores a program in advance has a management IC 66 and a reading terminal 68d. As a result, the signal paths for the reading terminal 68d can be integrated in the MPU 62. Therefore, it is possible to obtain the excellent effect as already described while making it difficult to illegally access the signal path to the reading terminal 68d.

The main CPU 63 that executes a process for paying out the game ball based on the game ball entering any one of the general winning opening 31, the special electric winning device 32, the first operating opening 33, and the second operating opening 34. A management CPU 112 is provided separately from the management CPU 112, and the management CPU 112 executes processing for storing history information in the history memory 117. As a result, it is possible to manage the entry mode of the game ball into each history target entry part while preventing the processing load of the main CPU 63 from increasing excessively.

The main CPU 63 and the management CPU 112 are provided on the same chip as the MPU 62. This makes it possible to prevent unauthorized access to the signal path between the main CPU 63 and the management CPU 112.

The main CPU 63 uses the signal paths corresponding to the detection results of the ball detection sensors 42a to 48a and the signal paths corresponding to the ball detection sensors 42a to 48a, respectively, to buffer the input port 121 of the management IC 66. 122a to 122g. As a result, the type of information transmitted from the main CPU 63 corresponds to each of the buffers 122a to 122g (that is, each signal path), and the configuration for distinguishing each type of information in the management CPU 112 is simplified. It becomes possible to do.

The main CPU 63 has information corresponding to whether the open/close execution mode is in effect, information corresponding to whether the high frequency support mode is in effect, information corresponding to whether the front door frame 14 is open, And the information corresponding to the start of the game game is transmitted to each of the buffers 122h to 122k of the input port 121 of the management IC 66 by using the signal paths corresponding to each of these situations. As a result, the type of information corresponding to each of these situations corresponds to each of the buffers 122h to 122k (that is, each signal path), and the configuration for distinguishing each type of information in the management side CPU 112 is simplified. It becomes possible.

The main CPU 63 transmits to the management CPU 112 correspondence information indicating which type of information each of the buffers 122a to 122k (that is, each of the signal paths 118a to 118k) corresponds to. As a result, it is not necessary to store the correspondence information in the management IC 66 in advance. Therefore, the versatility of the management IC 66 can be improved.

When the supply of operating power to the main CPU 63 is started, the correspondence information is transmitted from the main CPU 63 to the management IC 66. As a result, in a situation in which a game ball may enter the history-target entrance portion, the management IC 66 can identify the correspondence between the information transmitted from the main CPU 63 and the history-target entrance portion. It becomes possible to become.

Correspondence relationship information is transmitted from the main CPU 63 to the management IC 66 by using the signal paths 118a to 118g for transmitting information indicating whether or not the game sphere has entered the history target entry portion. This makes it possible to simplify the configuration related to communication as compared with the configuration in which a dedicated signal path for transmitting the correspondence information is provided.

The management IC 66 is provided with a correspondence memory 116, and the correspondence information transmitted from the main CPU 63 to the management IC 66 is stored in the correspondence memory 116. As a result, each time the main CPU 63 transmits the information of the detection result of each of the entrance detection sensors 42a to 48a, the information that enables the management target IC 66 to identify the history target entrance part corresponding to the information of the transmission target. Eliminates the need to provide. Therefore, it is possible to suppress the amount of information of the detection result of each of the ball detection sensors 42a to 48a transmitted from the main CPU 63.

Information is output from the management IC 66 to the reading terminal 68d by switching the output state of the output instruction signal output from the main CPU 63 to the management IC 66 from the LOW level to the HI level. In this case, the fact that the signal path corresponding to the 16th buffer 122p corresponds to the output instruction signal can be specified by the management-side CPU 112 without receiving the correspondence information from the main-side CPU 63. .. This makes it possible to prevent the configuration related to the transmission of the correspondence information from becoming extremely complicated.

The management IC 66 is provided with buffers 122a to 122p capable of receiving information from the main CPU 63, the number of which is larger than the number of types of information required to be transmitted from the main CPU 63 to the management IC 66. Has been. As a result, even when the number of types of the information increases or decreases according to the model of the pachinko machine 10, it is possible to deal with it without changing the configuration related to the buffers 122a to 122p. Therefore, the versatility of the management IC 66 can be improved.

When the history information is transmitted from the management IC 66 to the reading terminal 68d, the correspondence information indicating the type of the history-target ball entrance portion corresponding to the history information is included in each history information. As a result, it is possible to specify the entry mode of the game ball into each history target entry part by using the read history information.

By using the history information stored in the history memory 117 in the management IC 66, various parameters (first to eighth parameters, eleventh parameter, eleventh parameter) corresponding to the entering mode of the game ball in the game area PA in a predetermined period are used. ~ 18th parameter, 21st to 26th parameter, 31st parameter, 41st to 42nd parameter) are calculated. Then, various parameters resulting from these calculations are sequentially displayed on the first to third notification display devices 69a to 69c. As a result, it becomes possible for the pachinko machine 10 to notify various parameters that are the results of calculations using the history information.

Various parameters are calculated in a state where history information corresponding to the situation where the front door frame 14 is open is excluded. This makes it possible to derive various parameters in a normal situation where the front door frame 14 is in the closed state. In addition, various parameters corresponding to the open/close execution mode and the high-frequency support mode are calculated. As a result, it becomes possible for the manager of the game hall or the like to grasp the entering mode of the game ball according to each situation.

When the history information of the history memory 117 is output to the external device, the history memory 117 is initialized by executing the clear processing of the history memory 117. As a result, the history information that exceeds the storage capacity of the history memory 117 becomes a storage target in the history memory 117, and the history information that should normally be stored and retained is erased by overwriting. It becomes possible to make it difficult to generate.

When the game ball enters the first operation port 33 or the second operation port 34, an external output corresponding to the game ball is output through the external terminal board 97, and the history information is stored in the history memory 117. .. With this, by using the information output to the outside through the external terminal board 97, the history while easily grasping the number and the frequency of entering the game balls into the first operating opening 33 and the second operating opening 34. By using the history information stored in the memory 117 for use, it is possible to accurately grasp the number of game balls and the frequency of entering the game balls into the history target ball-in portion.

The probability of a jackpot result in the low-probability mode changes depending on the setting states of the "setting 1" to "setting 6" of the pachinko machine 10. As a result, even with a single pachinko machine 10, it is possible to cause a situation in which the probability of a jackpot result in the low-probability mode is advantageous or disadvantageous. Therefore, it becomes possible to improve the interest of the game.

The probability of a jackpot result in the low-probability mode varies depending on the setting state of the pachinko machine 10 of “setting 1” to “setting 6”, while the probability of a jackpot result in the high-probability mode is set by the pachinko machine 10. It does not change depending on the condition. This makes it possible to limit the influence of the setting state of the pachinko machine 10 to the probability of a jackpot result to the situation in the low-probability mode. Further, since the high probability table 64g referred to in the high probability mode can be made common regardless of the setting state of the pachinko machine 10, it is possible to preliminarily set the table 64a to 64g in the main ROM 64. It is possible to suppress an increase in storage capacity for storing.

The probability of a jackpot result in the low-probability mode varies according to the setting state of the pachinko machine 10 of "setting 1" to "setting 6", while the distribution mode of the types of jackpot results depends on the setting state of the pachinko machine 10. It does not change accordingly. This makes it possible to limit the influence of the setting state of the pachinko machine 10 to the situation in the low probability mode. Further, since it is possible to make the distribution table 64h referred to when distributing the types of jackpot results common to any of the setting states of the pachinko machine 10, the distribution table 64h in the main ROM 64. It is possible to suppress an increase in the storage capacity for storing in advance.

Even if a new setting state of the pachinko machine 10 is set, the history information stored in the history memory 117 is not erased but stored and retained. As a result, even if a new setting of the setting state of the pachinko machine 10 is performed, the history information up to that point can be continuously stored in the history memory 117, and the history memory can be stored for a long time. It is possible to specify the management result of the game history by using the history information accumulated in 117.

Even if the setting state of the pachinko machine 10 is newly set, in the configuration in which the history information stored in the history memory 117 is not erased but stored and retained, the setting state of the pachinko machine 10 is newly set. When the process is performed, the history information corresponding to it is stored in the history memory 117. As a result, it becomes possible to distinguish between the history information before the new setting of the setting state of the pachinko machine 10 and the history information after the new setting.

When the history information corresponding to it is stored in the history memory 117 by newly setting the setting state of the pachinko machine 10, the information corresponding to the set value is included in the history information. As a result, it becomes possible to specify the content of the setting value set in the past by referring to the history information.

When the set value update process (FIG. 10) is started, the set value is changed from the set value corresponding to the start that is set in advance. As a result, regardless of the setting value to be used before the setting value updating process (FIG. 10) is started, in the setting value updating process (FIG. 10), a change operation of the set value corresponding to a certain start is performed. Will be possible. Therefore, the work content of the operation of changing the set value becomes easy for the operator to understand.

Specifically, the setting value corresponding to the start is “setting 1” having the lowest advantage. Therefore, when the setting value updating process (FIG. 10) is started, the setting value is changed from “setting 1” having the lowest advantage. As a result, even if the manager of the game hall unintentionally terminates the set value update processing (FIG. 10) immediately after the start of the set value update processing (FIG. 10), the set value with the lowest advantage is set. Therefore, in such a situation, it is possible to prevent an unintended disadvantage from occurring in the game hall.

In addition, when various parameters are calculated at the calculation timing, the history information corresponding to a new setting of the setting state of the pachinko machine 10 in the history memory 117 is used as a reference and history information stored after that is used. Then, it may be configured to calculate various parameters. In this case, the management result of the game history at the timing after the new setting of the setting state of the pachinko machine 10 is performed can be derived as various parameters.

Further, when various parameters are calculated at the calculation timing, history information corresponding to a new setting of the setting state of the pachinko machine 10 in the history memory 117, and history information corresponding to a change of the set value is used as a reference. Alternatively, various parameters may be calculated using the history information stored after that. In this case, it becomes possible to derive the management result of the game history at the timing after the setting state of the pachinko machine 10 is changed as various parameters.

Although the board box 60a of the main controller 60 is provided with the opening for exposing the reading terminal 68d, the opening is not provided and the reading terminal 69d is provided on the opposite wall 60b. It may be configured to be covered by. In this case, it is necessary to open the substrate box 60a in order to connect an external device to the reading terminal 68d.

<Second Embodiment>
In the present embodiment, the contents of the hit/miss table corresponding to the setting state of the pachinko machine 10 are different from those of the first embodiment. The configuration different from that of the first embodiment will be described below. The description of the same configuration as that of the first embodiment is basically omitted.

FIG. 33 is an explanatory diagram for explaining various tables stored in the main ROM 64 in this embodiment.

As shown in FIG. 33, in the main ROM 64, a setting 1 area 161, a setting 2 area 162, a setting 3 area 163, a setting 4 area 164, a setting 5 area 165, and a setting 6 area. 166 are provided. In the setting 1 area 161, the low probability table 161a for setting 1 referred to when the setting state of the pachinko machine 10 is “setting 1” and the winning/winning lottery mode is the low probability mode, and the pachinko machine 10 are shown. The high probability table 161b for setting 1, which is referred to when the setting state of "is 1" and the winning/winning lottery mode is the high probability mode, is stored. In the setting 2 area 162, when the setting state of the pachinko machine 10 is “setting 2” and the winning/winning lottery mode is the low probability mode, the low probability table 162a for setting 2 which is referred to when the winning/winning lottery mode is the low probability mode and the pachinko machine 10 are provided. And the highly probable hit/miss table 162b for the setting 2 that is referred to when the win/win lottery mode is the high-probability mode. In the setting 3 area 163, the low probability table 163a for setting 3 which is referred to when the setting state of the pachinko machine 10 is “setting 3” and the winning/winning lottery mode is the low probability mode, and the pachinko machine 10 are provided. The high probability table 163b for setting 3, which is referred to when the setting state of “is 3” and the winning/winning lottery mode is the high probability mode, is stored.

In the setting 4 area 164, the low probability table 164a for setting 4 which is referred to when the setting state of the pachinko machine 10 is “setting 4” and the winning/winning lottery mode is the low probability mode, and the pachinko machine 10 are shown. The high probability table 164b for setting 4 which is referred to when the setting state of "is 4" and the winning/winning lottery mode is the high probability mode is stored. In the setting 5 area 165, the low-probability/probability table 165a for setting 5, which is referred to when the setting state of the pachinko machine 10 is “setting 5” and the winning/winning lottery mode is the low probability mode, and the pachinko machine 10 are provided. And a high probability table 165b for setting 5, which is referred to when the setting state of “is 5” and the winning/winning lottery mode is the high probability mode. In the setting 6 area 166, the low probability table 166a for setting 6 which is referred to when the setting state of the pachinko machine 10 is “setting 6” and the winning/winning lottery mode is the low probability mode, and the pachinko machine 10 are shown. The high-probability/probability table 166b for setting 6, which is referred to when the setting state of “is 6” and the win/loss lottery mode is the high probability mode, is stored.

The winning probabilities of the jackpot results set in each of the low certainty win/loss tables 161a to 166a are different from each other. Specifically, when the low-probability/probability table 161a for setting 1 is referenced, the jackpot result is about 1/320, and when the low-probability/probability table 162a for setting 2 is referenced, it is approximately 1/310. Results in a big hit, about 1/300 when the low probability table 163a for setting 3 is referred to, and about 1/290 when a low probability table 164a for setting 4 is referenced. Results in a big hit, about 1/280 when the low probability table 165a for setting 5 is referred to, and about 1/270 when a low accuracy table 166a for setting 6 is referred to. The result is a big hit. As a result, when the setting state of the pachinko machine 10 is a high setting value, a jackpot result is more likely to occur in the low-probability mode, which is advantageous for the player.

The winning probabilities of the jackpot results set in the high-probability winning/losing tables 161b to 166b are different from each other. Specifically, when the high-probability/probability table 161b for setting 1 is referenced, the jackpot result is about 1/45, and when the high-probability/probability table 162b for setting 2 is referenced, it is about 1/40. Results in a big hit, and when the high-accuracy hit/miss table 163b for setting 3 is referred to, the jackpot result is obtained at about 1/35. When the high-accuracy hit/miss table 164b for setting 4 is referred to, approximately 1/30 Results in a big hit, and when the high-accuracy hit/miss table 165b for setting 5 is referred to, the result is about 1/25. When the high-accuracy hit/miss table 166b for setting 6 is referred, it is about 1/20. The result is a big hit. As a result, when the set state of the pachinko machine 10 is a high set value, a jackpot result is more likely to occur in the high-probability mode, which is advantageous for the player.

That is, in the first embodiment, the winning probability of the jackpot result in the low probability mode becomes higher as the setting state of the pachinko machine 10 becomes higher, while the winning probability of the jackpot result in the high probability mode becomes “Setting 1”. Although the configuration is common in any of the setting states of “setting 6”, in the present embodiment, both the winning probability of the jackpot result in the low-probability mode and the winning probability of the jackpot result in the high-probability mode are pachinko. The higher the setting value of the machine 10, the higher the setting value. As a result, it is possible to increase the player's advantage with respect to the fact that a high set value is set.

In addition, even if the winning probability of the jackpot result of the low probability mode in the case of the highest setting state "setting 6", the winning of the jackpot result of the high probability mode in the case of the lowest setting state "setting 1" It is set lower than the probability. As a result, it is possible to prevent the player's advantage when the setting state of the pachinko machine 10 is “setting 1” from becoming extremely low, and the setting state of the pachinko machine 10 is “setting”. It is possible to prevent the player's advantage in the case of "6" from becoming extremely high.

On the other hand, as in the first embodiment, only one sort table 64h is provided so as to be common in any of the setting states of “setting 1” to “setting 6”. As a result, it is possible to prevent the distribution state of the jackpot result from being advantageous or disadvantageous depending on the setting state of the pachinko machine 10, and a storage capacity for storing the distribution table 64h in the main ROM 64 in advance. Can be suppressed.

The winning probability of the jackpot result in the low probability mode is higher when the setting state of the pachinko machine 10 is higher, whereas the winning probability of the jackpot result in the high probability mode is higher in the setting state of the pachinko machine 10. The configuration may be such that the set value is lower. In this case, in the low probability mode, the higher the setting value of the pachinko machine 10 is, the more advantageous the player is to the setting value, and in the high probability mode, the lower the setting value of the pachinko machine 10 is, the better the setting value is to the player. It becomes possible.

The winning probability of the jackpot result in the high-probability mode is higher when the setting state of the pachinko machine 10 is higher, while the winning probability of the jackpot result in the low-probability mode is “setting 1” to “setting 6”. The configuration may be constant in the setting state of ". In this case, in the high-probability mode, the higher the setting state of the pachinko machine 10 is, the more advantageous the player is for the setting value, and in the low-probability mode, it is possible to prevent the advantage or disadvantage of the pachinko machine 10 from being set. Become.

<Third Embodiment>
In this embodiment, the management result of the game history when the setting state of the pachinko machine 10 is newly set is different from that of the first embodiment. The configuration different from that of the first embodiment will be described below. The description of the same configuration as that of the first embodiment is basically omitted.

The management IC 66 is provided with a separate storage memory 171 as a memory for storing information, in addition to the memories in the first embodiment. FIG. 34 is an explanatory diagram for explaining the separate storage memory 171. The separate storage memory 171 is a memory such as a NOR flash memory and a NAND flash memory that does not require external power supply for storage storage (that is, a non-volatile storage unit), and is used for both reading and writing.

The separate storage memory 171 is provided with a first separate storage area 172, a second separate storage area 173, a third separate storage area 174, a fourth separate storage area 175, and a fifth separate storage area 176. Information of the management result of the game history calculated when the setting state of the pachinko machine 10 is newly set in these first to fifth separate storage areas 172 to 176, more specifically, the first embodiment. The various parameters described in (1st to 8th parameters, 11th to 18th parameters, 21st to 26th parameters, 31st parameter, 41st to 42nd parameters) are sequentially stored. In this case, when the setting state of the pachinko machine 10 is newly set, various parameters are first stored in the first separate storage area 172, and thereafter, every time the setting state of the pachinko machine 10 is newly set, the n-th type. The areas to be stored are switched so that the storage areas 172 to 176 → the (n+1)th storage areas 172 to 176 are stored. When the setting state of the pachinko machine 10 is newly set after the various parameters are stored in the fifth separate storage area 176, the various parameters are stored again in the first separate storage area 172. At this time, the various parameters already stored in the first separate storage area 172 are erased. As a result, various parameters until the new setting of the setting state of the pachinko machine 10 is executed 5 times are stored in the separate storage memory 171, and the oldest various parameters are erased when the number of times exceeds 5 times. It will be remembered.

The various parameters stored in the first to fifth separate storage areas 172 to 176 can be read by the external device by connecting the external device to the reading terminal 68d. As a result, it becomes possible to grasp the management result of the game history before the new setting of the setting state is performed in the pachinko machine 10.

Next, the setting update recognition process in this embodiment executed by the management-side CPU 112 will be described with reference to the flowchart of FIG.

When the set value update signal input to the fifteenth buffer 122o of the input port 121 switches from the LOW level to the HI level (step S1801: YES), the value of the set value grasping counter in the management side RAM 114 is set to "1". It is set (step S1802). The set value grasping counter is a counter for the management side CPU 112 to specify the set value of the pachinko machine 10. For example, if the value of the set value grasping counter is "1", it means "setting 1", If the value of the setting value grasping counter is "6", it means "setting 6".

After that, it is determined whether or not the setting value update signal input to the fifteenth buffer 122o of the input port 121 has switched from the LOW level to the HI level again (step S1803). If an affirmative decision is made in step S1803, the value of the set value grasping counter in the management side RAM 114 is incremented by 1 (step S1804). As a result, the set value of the pachinko machine 10 specified by the management-side CPU 112 is increased by one step.

When a negative determination is made in step S1803 or when the process of step S1804 is executed, based on the input states of the first to eighth signals input to the first to eighth buffers 122a to 122h of the input port 121. Then, it is determined whether or not a setting value identification end command has been received from the main CPU 63 (step S1805). When a negative determination is made in step S1805, the process returns to step S1803.

If an affirmative decision is made in step S1805, repeated change monitoring processing is executed (step S1806). Although details of the repeated change monitoring process will be described later, when a new setting of the setting state of the pachinko machine 10 repeatedly occurs in a short period of time, a process for notifying it is executed. In the configuration in which various parameters are stored in the separate storage memory 171 every time a new setting of the setting state of the pachinko machine 10 is performed, the management result of the game history when the game is played for a predetermined period is intended. It is assumed that new setting of the setting state of the pachinko machine 10 is repeatedly performed in a short period of time so as to be erased automatically. On the other hand, by repeatedly performing the change monitoring process, when such an action is performed, the corresponding notification is performed.

After that, various arithmetic processes are executed (step S1807). In various calculation processes, the processes of steps S1402 to S1412 of the display output process (FIG. 30) in the first embodiment are executed. Thereby, various parameters (first to eighth parameters, eleventh to eighteenth parameters, twenty-first to twenty-sixth parameters, thirty-first parameters and fourteenth parameters) are utilized by utilizing the history information stored in the history memory 117 at that time. ~ 42nd parameter) is calculated.

After that, the various parameters calculated in step S1807 are stored in the areas to be stored this time among the first to fifth separate storage areas 172 to 176 of the separate storage memory 171 (step S1808). In the separate storage memory 171, a pointer information area is set so that the management CPU 112 can specify an area to be stored among the first to fifth separate storage areas 172 to 176. Information of the pointer information area is changed so that when various parameters are stored in the storage target area of the first to fifth separate storage areas 172 to 176, the storage area is changed to the next order area. Will be updated. By executing the processing of step S1808, various parameters at that time are stored in the separate storage memory 171 for the new setting of the setting state of the pachinko machine 10 this time.

After that, the history memory 117 is cleared to "0" (step S1809). That is, in the present embodiment, not only when the history information is read by the external device connected to the reading terminal 68d, but also when the setting state of the pachinko machine 10 is newly set, the history memory The history information 117 is deleted.

After that, the RTC information which is the date information and the time information is read from the RTC 115 (step S1810). Then, the writing process to the history memory 117 is executed (step S1811). In the writing process, the pointer area 126 of the history memory 117 is referred to identify the pointer information of the history area 124 that is the current writing target, and the pointer information corresponding to the pointer information of the writing target is specified. The RTC information read in step S1810 is written in the history information storage area 125 of the history area 124. Further, both the information for identifying the set value and the value information of the set value grasping counter are written in the history information storage area 125 corresponding to the pointer information to be written. Thereby, the information indicating that the setting state of the pachinko machine 10 is newly set, the RTC information corresponding to the date and time when the setting is performed, and the information of the setting value when the setting is performed, The combination is stored as history information.

After that, the target pointer is updated (step S1812). In the update processing, the numerical information stored in the pointer area 126 of the history memory 117 is read and 1 is added. It is determined whether or not the pointer information after the addition of 1 exceeds the maximum value of the pointer information in the history area 124. If the maximum value is not exceeded, the pointer information after adding 1 is overwritten in the pointer area 126 as new pointer information to be written. If the maximum value is exceeded, the pointer area 126 is cleared to "0" so that the pointer information to be written becomes the first pointer information.

Next, the repetitive change monitoring process executed in step S1806 will be described with reference to the flowchart in FIG.

First, it is determined whether or not the number of game times executed since the setting state of the pachinko machine 10 was set last time is within a reference number of times (specifically, 100 times) (step S1901). Specifically, the setting of the pachinko machine 10 is performed by counting the number of history information storage areas 125 in which the correspondence information indicating the start of game times is stored in the history area 124 of the history memory 117. The number of game times executed since the state was set last time is grasped, and it is further judged whether or not the grasped number of game times is within a reference number (specifically, 100 times).

When a positive determination is made in step S1901, the value of the repeat change counter provided in the separate storage memory 171 is incremented by 1 (step S1902). Since the separate storage memory 171 is a memory that does not require external power supply for storage and storage as already described, the external storage does not require power supply for storage of the repeated change counter value.

Then, it is determined whether or not the value of the repeat change counter after adding 1 exceeds the notification reference value "5" (step S1903). The notification reference value corresponds to the number of the first to fifth separate storage areas 172 to 176 provided in the separate storage memory 171. Therefore, in step S1903, the number of times the new setting of the setting state of the pachinko machine 10 is repeated without the execution of the game times exceeding the reference number of times is the number of the first to fifth separate storage areas 172 to 176. It is determined whether or not it has exceeded.

When an affirmative determination is made in step S1903, display processing of repeated changes is executed (step S1904). In the display process of the repeated change, the display contents of the first to third notification display devices 69a to 69c correspond to the new setting of the setting state of the pachinko machine 10 being repeated a number of times exceeding the notification reference value in a short period of time. It is the display content of repeated changes. The display content of the repeated change is the display content that displays "E" on all of the first to third notification display devices 69a to 69c, and this display content does not occur in other situations. Further, the state in which the display content of the repeated change is displayed on the first to third notification display devices 69a to 69c is continued until the repeated change flag provided in the separate storage memory 171 is cleared to "0". .. The repeat change flag is a flag for the management CPU 112 to specify that the display contents of the repeat change should be displayed on the first to third notification display devices 69a to 69c. Further, when the repeated change flag is set to "1" and the display contents of the repeated change are displayed on the first to third notification display devices 69a to 69c, the display process in the first embodiment described above. (FIG. 31) is not executed. After that, "1" is set to the repeat change flag of the separate storage memory 171 (step S1905).

When a negative determination is made in step S1901, the value of the repeat change counter of the separate storage memory 171 is cleared to "0" (step S1906). After that, on condition that the repeated change flag of the separate storage memory 171 is set to "1" (step S1907: YES), the display contents of the repeated changes on the first to third notification display devices 69a to 69c are displayed. The display is terminated (step S1908), and the repeat change flag is cleared to "0" (step S1909).

According to this embodiment described in detail above, the following excellent effects are exhibited.

When a new setting of the setting state of the pachinko machine 10 is performed, the history information stored in the history memory 117 is erased. Thereby, it becomes possible to leave the history information of the game executed after the new setting of the setting state of the pachinko machine 10 in the history memory 117.

When the setting state of the pachinko machine 10 is newly set, various parameters are calculated as the management result of the game history by using the history information of the history memory 117 at that time. Thereby, it becomes possible to grasp the management result of the game history in the situation before the new setting of the setting state is performed in the pachinko machine 10. Further, even if the history information in the history memory 117 is deleted when a new setting of the setting state of the pachinko machine 10 is performed, it is possible to grasp the management result of the game history by the history information to be deleted. It will be possible.

In a configuration in which various parameters are calculated using the history information of the history memory 117 at that time when a new setting state is set in the pachinko machine 10, the calculated various parameters are stored in a separate storage memory. 171 is stored. As a result, even if a new setting state is set in the pachinko machine 10, it is possible to grasp the management result of the game history in a situation before the setting is performed at an arbitrary timing thereafter.

By providing the plurality of separate storage areas 172 to 176 in the separate storage memory 171, it becomes possible to store various parameters corresponding to the setting timing of the setting state for a plurality of times. Thereby, it becomes possible to grasp the management result of the game history in a plurality of periods with reference to the timing when the new setting of the setting state is performed. Further, even if new setting of the setting state of the pachinko machine 10 is repeated under the situation where the game is not played, various parameters calculated by using the history information of the situation where the game is practically played are It is possible to increase the possibility of remaining in the separate storage memory 171.

The various parameters stored in the first to fifth separate storage areas 172 to 176 can be read by the external device by connecting the external device to the reading terminal 68d. As a result, it becomes possible to grasp the management result of the game history before the new setting of the setting state is performed in the pachinko machine 10.

In the configuration in which various parameters are stored in the separate storage memory 171 every time a new setting of the setting state of the pachinko machine 10 is performed, the management result of the game history when the game is played for a predetermined period is intended. It is assumed that new setting of the setting state of the pachinko machine 10 is repeatedly performed in a short period of time so as to be erased automatically. On the other hand, by repeatedly performing the change monitoring process, when such an action is performed, the corresponding notification is performed. As a result, it becomes possible to notify an administrator or the like that new setting of the setting state of the pachinko machine 10 has been repeatedly performed in a short period of time.

The notification that the new setting state of the pachinko machine 10 is repeatedly performed in a short period of time is performed by the first to third notification display devices 69a to 69c. Thereby, by using the first to third notification display devices 69a to 69c for notifying the management result of the game history, new setting of the setting state of the pachinko machine 10 is repeatedly performed in a short period of time. It is possible to make a notification.

In a situation where it is necessary to notify that the new setting of the setting state of the pachinko machine 10 has been repeatedly performed in a short period of time, the display contents of the repeated change are continuously displayed on the first to third notification display devices 69a to 69c. The notification of the game history management result at the normal time is not performed on the first to third notification display devices 69a to 69c. Thereby, it becomes possible to emphasize the notification that the new setting of the setting state of the pachinko machine 10 has been repeatedly performed in a short period.

In addition, when the number of game times executed after the new setting of the setting state of the pachinko machine 10 is performed is within the reference number of times, the event in which the new setting is performed continues beyond the notification reference value. However, the present invention is not limited to this, and the total discharge of the game balls discharged from the game area PA after the new setting of the setting state of the pachinko machine 10 is performed. In a situation where the number is within the reference number, if the event in which the new setting is performed exceeds the notification reference value and continues, a corresponding notification may be executed. In addition, after a new setting of the setting state of the pachinko machine 10 is performed, a predetermined ball entrance portion (for example, any one of the out opening 24a, the general winning opening 31, the first operation opening 33, and the second operation opening 34 or a predetermined operation opening). In the situation where the total number of discharged game balls entered in (combination) is within the reference number and the event for which the new setting is performed continues beyond the notification reference value, the corresponding notification may be executed. Good. In addition, when the total number of history information items newly stored in the history memory 117 after the new setting of the setting state of the pachinko machine 10 is performed is within the reference number, the event of the new setting is notified. It is also possible to adopt a configuration in which when the number exceeds the reference value and continues, the corresponding notification is executed.

Further, when a new setting of the setting state of the pachinko machine 10 is executed within the monitoring reference period (for example, 600 seconds) exceeding the notification reference value, the corresponding notification may be executed.

Further, in the situation where the number of game times executed after the new setting of the setting state of the pachinko machine 10 is performed is within the reference number of times, the event in which the new setting is performed continuously exceeds the notification reference value. Although the notification corresponding to it is configured to be executed, the set value is changed in a situation where the number of game times executed after the new setting of the setting state of the pachinko machine 10 is performed is within the reference number of times. It is also possible to adopt a configuration in which when an event exceeds the notification reference value and continues, the corresponding notification is executed.

Further, in the situation where the number of game times executed after the new setting of the setting state of the pachinko machine 10 is performed is within the reference number of times, the event in which the new setting is performed continuously exceeds the notification reference value. Although the notification corresponding to that is executed, the new setting is triggered when the number of game times executed after the new setting of the setting state of the pachinko machine 10 is within the reference number. When the event in which the various parameters are calculated exceeds the notification reference value and continues, the corresponding notification may be executed.

Further, in the situation where the number of game times executed after the new setting of the setting state of the pachinko machine 10 is performed is within the reference number of times, the event in which the new setting is performed continuously exceeds the notification reference value. Although the notification corresponding to the above is executed, the game progress may be restricted in addition to or instead of that for a predetermined period (for example, one hour).

<Fourth Embodiment>
The present embodiment is different from the third embodiment in that the monitoring process of repeated changes is executed by the main CPU 63. The configuration different from that of the third embodiment will be described below. The description of the same configuration as that of the third embodiment is basically omitted.

FIG. 37 is a flow chart showing the monitoring process of repeated changes executed by the main CPU 63. It should be noted that the repeated change monitoring process is executed when the set value update process (step S118) is executed in the main process (FIG. 9). That is, when the setting state of the pachinko machine 10 is newly set, the change monitoring process is repeatedly executed. However, the present invention is not limited to this, and it is also possible to adopt a configuration in which the monitoring process of repeated change is executed when the set value is changed.

First, it is determined whether or not the number of game times executed since the setting state of the pachinko machine 10 was set last time is within a reference number (specifically 100 times) (step S2001). The main RAM 65 is provided with a game number counter for measuring the number of game times executed after the setting state of the pachinko machine 10 is newly set, and the main CPU 63 newly executes the game times. Each time, the value of the game number counter is incremented by 1. The game number counter is excluded from the target of "0" clear even when the clear process (step S105, step S117) of the main RAM 65 is executed.

When a positive determination is made in step S2001, the value of the repeat change counter provided in the main RAM 65 is incremented by 1 (step S2002). The repetitive change counter is excluded from the target of clearing "0" even when the clearing process of the main RAM 65 (steps S105 and S117) is executed.

Then, it is determined whether or not the value of the repeat change counter after adding 1 exceeds the notification reference value "5" (step S2003). The notification reference value corresponds to the number of the first to fifth separate storage areas 172 to 176 provided in the separate storage memory 171. Therefore, in step S2003, the number of times the new setting of the setting state of the pachinko machine 10 is repeated without the execution of the game times exceeding the reference number of times is the number of the first to fifth separate storage areas 172 to 176. It is determined whether or not it has exceeded.

When a positive determination is made in step S2003, "1" is set to the repeat change flag provided in the main RAM 65 (step S2004). The repetitive change flag is a flag for the main CPU 63 to specify that the repetitive change should be notified. The repetitive change flag is excluded from the target of clearing "0" even when the clear process (step S105, step S117) of the main RAM 65 is executed.

When a negative determination is made in step S2001, the value of the repeat change counter of the main RAM 65 is cleared to "0" (step S2005). After that, on condition that the repeat change flag of the main RAM 65 is set to "1" (step S2006: YES), the repeat change flag is cleared to "0" (step S2007).

In the repeated change monitoring process, when "1" is set in the repeated change flag of the main RAM 65 (step S2008: YES), a repeated change notification command is transmitted to the sound emission control device 81 (step S2009). When the sound emission control device 81 receives the notification command of repeated changes, the symbol display device 41, the display light emitting unit 53, and the speaker unit 54 notify the repeated changes. The notification of the repeated change is continued until the supply of operating power to the sound emission control device 81 is stopped.

According to the above configuration, it is possible to notify that new setting of the setting state of the pachinko machine 10 has been repeatedly performed in a short period of time based on the control by the main CPU 63. Further, since the notification is performed by the symbol display device 41, the display light emitting unit 53, and the speaker unit 54, even if the gaming machine main body 12 is not opened forward with respect to the outer frame 11, the setting state of the pachinko machine 10 It becomes possible for the administrator to recognize that the new setting has been repeated in a short period of time.

When a new setting of the setting state of the pachinko machine 10 is repeatedly performed in a short period of time, in addition to or instead of the configuration in which the notification command of the repeated change is transmitted from the main CPU 63 to the sound emission control device 81, A configuration may be adopted in which external output corresponding thereto is performed.

Further, the main CPU 63 may execute the repeated change monitoring process in this embodiment, and the management side CPU 112 may execute the repeated change monitoring process in the third embodiment. As a result, it becomes possible to strictly monitor whether a new setting state of the pachinko machine 10 is repeatedly set in a short period of time.

<Fifth Embodiment>
In the present embodiment, the processing configuration of the setting update recognition processing in the management side CPU 112 is different from that of the third embodiment. The configuration different from that of the third embodiment will be described below. The description of the same configuration as that of the third embodiment is basically omitted.

FIG. 38 is a flow chart showing the setting update recognition process executed by the management CPU 112 in this embodiment.

When the set value update signal input to the fifteenth buffer 122o of the input port 121 switches from the LOW level to the HI level (step S2101: YES), the value of the set value grasping counter in the management side RAM 114 is set to "1". It is set (step S2102). The set value grasping counter is a counter for the management side CPU 112 to specify the set value of the pachinko machine 10. For example, if the value of the set value grasping counter is "1", it means "setting 1", If the value of the setting value grasping counter is "6", it means "setting 6".

After that, it is determined whether or not the set value update signal input to the fifteenth buffer 122o of the input port 121 has switched from the LOW level to the HI level again (step S2103). When an affirmative determination is made in step S2103, the value of the set value grasping counter in the management side RAM 114 is incremented by 1 (step S2104). As a result, the set value of the pachinko machine 10 specified by the management-side CPU 112 is increased by one step.

When a negative determination is made in step S2103, or when the processing of step S2104 is executed, based on the input states of the first to eighth signals input to the first to eighth buffers 122a to 122h of the input port 121. Then, it is determined whether or not a setting value identification end command has been received from the main CPU 63 (step S2105). When a negative determination is made in step S2105, the process returns to step S2103.

When a positive determination is made in step S2105, it is determined whether or not a predetermined number or more of predetermined history information is present in the history memory 117 (step S2106). Specifically, the setting of the pachinko machine 10 is performed by counting the number of history information storage areas 125 in which the correspondence information indicating the start of game times is stored in the history area 124 of the history memory 117. The number of game times executed since the state was set last time is grasped, and it is further determined whether or not the grasped number of game times exceeds a reference number (specifically 100 times). However, the number is not limited to this, and the number of history information storage areas 125 in which the correspondence information indicating that the game balls have been discharged from the game area PA is stored is a reference number (specifically 1000). It may be configured to determine in step S2106 whether or not it exceeds. Correspondence relationship information indicating that the game ball has entered a predetermined ball entrance portion (for example, any one of the outlet 24a, the general winning opening 31, the first operation opening 33, and the second operation opening 34 or a predetermined combination) It may be configured to determine in step S2106 whether or not the number of history information storage areas 125 in which is stored exceeds the reference number (specifically, 1000). Further, it may be configured to determine in step S2106 whether the total number of history information stored in the history memory 117 (specifically, 1000) is exceeded.

In addition, when the number of game times executed after the new setting of the setting state of the pachinko machine 10 is performed is within the reference number of times, the event in which the new setting is performed continues beyond the notification reference value. However, the present invention is not limited to this, and the total discharge of the game balls discharged from the game area PA after the new setting of the setting state of the pachinko machine 10 is performed. In a situation where the number is within the reference number, if the event in which the new setting is performed exceeds the notification reference value and continues, a corresponding notification may be executed. In addition, after a new setting of the setting state of the pachinko machine 10 is performed, a predetermined ball entrance portion (for example, any one of the out opening 24a, the general winning opening 31, the first operation opening 33, and the second operation opening 34 or a predetermined operation opening). In the situation where the total number of discharged game balls entered in (combination) is within the reference number and the event for which the new setting is performed continues beyond the notification reference value, the corresponding notification may be executed. Good. In addition, when the total number of history information items newly stored in the history memory 117 after the new setting of the setting state of the pachinko machine 10 is performed is within the reference number, the event of the new setting is notified. It is also possible to adopt a configuration in which when the number exceeds the reference value and continues, the corresponding notification is executed.

When an affirmative determination is made in step S2106, various arithmetic processes are executed (step S2107). In various calculation processes, the processes of steps S1402 to S1412 of the display output process (FIG. 30) in the first embodiment are executed. Thereby, various parameters (first to eighth parameters, eleventh to eighteenth parameters, twenty-first to twenty-sixth parameters, thirty-first parameters and fourteenth parameters) are utilized by utilizing the history information stored in the history memory 117 at that time. ~ 42nd parameter) is calculated.

After that, the various parameters calculated in step S2107 are stored in the areas to be stored this time among the first to fifth separate storage areas 172 to 176 of the separate storage memory 171 (step S2108). In the separate storage memory 171, a pointer information area is set so that the management CPU 112 can specify an area to be stored among the first to fifth separate storage areas 172 to 176. Information of the pointer information area is changed so that when various parameters are stored in the storage target area of the first to fifth separate storage areas 172 to 176, the storage area is changed to the next order area. Will be updated. By executing the process of step S2108, various parameters at that time are stored in the separate storage memory 171 for the new setting of the setting state of the pachinko machine 10 this time.

If a negative determination is made in step S2106, or if the process of step S2108 is executed, the history memory 117 is cleared to "0" (step S2109). That is, in the present embodiment, not only when the history information is read by the external device connected to the reading terminal 68d, but also when the setting state of the pachinko machine 10 is newly set, the history memory The history information 117 is deleted.

After that, the RTC information which is the date information and the time information is read from the RTC 115 (step S2110). Then, the writing process to the history memory 117 is executed (step S2111). In the writing process, the pointer area 126 of the history memory 117 is referred to identify the pointer information of the history area 124 that is the current writing target, and the pointer information corresponds to the writing target pointer information. The RTC information read in step S2110 is written in the history information storage area 125 of the history area 124. Further, both the information for identifying the set value and the value information of the set value grasping counter are written in the history information storage area 125 corresponding to the pointer information to be written. Thereby, the information indicating that the setting state of the pachinko machine 10 is newly set, the RTC information corresponding to the date and time when the setting is performed, and the information of the setting value when the setting is performed, The combination is stored as history information.

After that, update processing of the target pointer is executed (step S2112). In the update processing, the numerical information stored in the pointer area 126 of the history memory 117 is read and 1 is added. It is determined whether or not the pointer information after the addition of 1 exceeds the maximum value of the pointer information in the history area 124. If the maximum value is not exceeded, the pointer information after adding 1 is overwritten in the pointer area 126 as new pointer information to be written. If the maximum value is exceeded, the pointer area 126 is cleared to "0" so that the pointer information to be written becomes the first pointer information.

According to the above configuration, when the setting state of the pachinko machine 10 is newly set, the history memory 117 is stored in the history memory 117 on condition that a predetermined number or more of history information is stored. Various parameters are calculated using the history information, and the various parameters are stored in the separate storage memory 171. As a result, even if a new setting of the setting state of the pachinko machine 10 is repeatedly performed in a short period of time, the information of the management result of the game history as a result of the game being substantially executed is stored in the separate storage memory 171. It becomes possible to be stored.

Note that the process of step S2109 may be executed on condition that the processes of steps S2107 and S2108 are executed. That is, the history information stored in the history memory 117 is erased on condition that a predetermined number or more of history information is stored in the history memory 117. This makes it possible to prevent the history information in the history memory 117 from being erased even if a new setting state of the pachinko machine 10 is repeatedly performed in a short period of time.

<Sixth Embodiment>
In this embodiment, the structure of the history memory 117 is different from that of the first embodiment. The configuration different from that of the first embodiment will be described below. The description of the same configuration as that of the first embodiment is basically omitted.

FIG. 39 is an explanatory diagram for explaining the configuration of the history memory 117 in this embodiment.

The history memory 117 is provided with a total area 141, a first state area 142, a second state area 143, and a third state area 144. First to fourteenth counters 141a to 141n, 142a to 142n, 143a to 143n, 144a to 144n are provided in each of these areas 141 to 144, respectively. Information on the number of times the output state of the first signal input to the first buffer 122a is changed from the LOW level to the HI level is stored in the first counters 141a to 144a of each of the areas 141 to 144. Information on the number of times the output state of the second signal input to the second buffer 122b is changed from the LOW level to the HI level is stored in the second counters 141b to 144b of each of the areas 141 to 144. Information about the number of times the output state of the third signal input to the third buffer 122c is changed from the LOW level to the HI level is stored in the third counters 141c to 144c of each of the areas 141 to 144. Information on the number of times the output state of the fourth signal input to the fourth buffer 122d is changed from the LOW level to the HI level is stored in the fourth counters 141d to 144d of each of the areas 141 to 144. Information on the number of times the output state of the fifth signal input to the fifth buffer 122e is changed from the LOW level to the HI level is stored in the fifth counters 141e to 144e of each of the areas 141 to 144. The sixth counters 141f to 144f of the areas 141 to 144 store information on the number of times the output state of the sixth signal input to the sixth buffer 122f is changed from the LOW level to the HI level. Information on the number of times the output state of the seventh signal input to the seventh buffer 122g is changed from the LOW level to the HI level is stored in the seventh counters 141g to 144g of each of the areas 141 to 144. Information on the number of times the output state of the eighth signal input to the eighth buffer 122h is changed from the LOW level to the HI level is stored in the eighth counters 141h to 144h of each of the areas 141 to 144. Information on the number of times the output state of the ninth signal input to the ninth buffer 122i is changed from the LOW level to the HI level is stored in the ninth counters 141i to 144i of each area 141 to 144. Information on the number of times the output state of the tenth signal input to the tenth buffer 122j is changed from the LOW level to the HI level is stored in the tenth counters 141j to 144j of each of the areas 141 to 144. Information on the number of times the output state of the eleventh signal input to the eleventh buffer 122k is changed from the LOW level to the HI level is stored in the eleventh counters 141k to 144k in each of the areas 141 to 144. Information on the number of times the output state of the twelfth signal input to the twelfth buffer 122l is changed from the LOW level to the HI level is stored in the twelfth counters 141l to 144l of each of the areas 141 to 144. Information on the number of times the output state of the thirteenth signal input to the thirteenth buffer 122m is changed from the LOW level to the HI level is stored in the thirteenth counters 141m to 144m of each of the areas 141 to 144. The 14th counters 141n to 144n of the areas 141 to 144 store information on the number of times the output state of the 14th signal input to the 14th buffer 122n is changed from the LOW level to the HI level.

FIG. 40 is a flowchart showing the history setting process executed by the management CPU 112 in this embodiment.

First, the number of buffers to be confirmed in the management CPU 112 among the first to fourteenth buffers 122a to 122n is set in the confirmation target counter of the management RAM 114 (step S2201). Specifically, of the first to fourteenth correspondence areas 123a to 123n in the correspondence memory 116, the number of correspondence areas in which information other than the information indicating blank is stored is specified, and the identification is performed. The information of the number that was set is set in the check target counter. In the present pachinko machine 10, since information other than information indicating that it is blank is stored in the first to eleventh correspondence areas 123a to 123k, "11" is set in the confirmation target counter in step S2201.

After that, it is determined whether or not the buffers 122a to 122n corresponding to the current check target counter are buffers to which the signal of the status information is input (step S2202). Specifically, in the correspondence areas 123a to 123n corresponding to the current value of the check target counter, as correspondence information, information indicating the open/close execution mode, information indicating the high frequency support mode, and It is determined whether any of the information indicating the front door frame 14 is stored.

If an affirmative decision is made in step S2202, state information setting processing is executed (step S2203). In the setting process, when the output state of the eighth signal indicating whether or not the open/close execution mode is switched from the LOW level to the HI level, the information of the first state indicating that the open/close execution mode is set is displayed on the management side. When the output state of the eighth signal is switched from the HI level to the LOW level, it is stored in the RAM 114, and the information of the first state is deleted from the management side RAM 114. Further, when the output state of the ninth signal indicating whether or not the high frequency support mode is switched from the LOW level to the HI level, the information of the second state indicating that the high frequency support mode is in progress is provided to the management side RAM 114. When the output state of the ninth signal is switched from the HI level to the LOW level, the information on the second state is erased from the management side RAM 114. In addition, when the output state of the tenth signal indicating whether the front door frame 14 is open is switched from the LOW level to the HI level, the third state information indicating that the front door frame 14 is open Is stored in the management RAM 114, and when the output state of the tenth signal is switched from the HI level to the LOW level, the information of the third state is erased from the management RAM 114.

If a negative determination is made in step S2202, or if the process of step S2203 is executed, the numerical value information stored in the buffer corresponding to the current value of the check target counter among the first to fourteenth buffers 122a to 122n is , It is determined whether or not the output state of the input signal from the main CPU 63 to the buffer has been switched from the LOW level to the HI level by checking whether or not it has been changed from “0” to “1” ( Step S2204). In addition, when the numerical value information stored in the eighth buffer 122h is changed from “0” to “1” in a situation where the current value of the check target counter is the value corresponding to the eighth buffer 122h, the process proceeds to step S2203. Information of the first state is stored in the management side RAM 114, and a positive determination is made in step S2204. If the numerical value information stored in the ninth buffer 122i is changed from “0” to “1” in a situation where the current value of the check target counter is the value corresponding to the ninth buffer 122i, the process proceeds to step S2203. Information of the second state is stored in the management side RAM 114, and a positive determination is made in step S2204. If the numerical value information stored in the tenth buffer 122j is changed from “0” to “1” in a situation where the current value of the check target counter is the value corresponding to the tenth buffer 122j, the process proceeds to step S2203. The information of the third state is stored in the management side RAM 114, and a positive determination is made in step S2204.

When an affirmative determination is made in step S2204, the corresponding summing counter addition processing is executed (step S2205). In the addition processing, the value of the counter corresponding to the current value of the check target counter among the first to fourteenth counters 141a to 141n for summing in the summing area 141 of the history memory 117 is incremented by 1. For example, if the value of the check target counter is “11”, the total eleventh counter 141k is the addition target, and if the check target counter value is “5”, the total fifth counter 141e is the addition target, If the value of the confirmation target counter is "1", the first total counter 141a will be the addition target.

Thereafter, by referring to the state information of the management side RAM 114, it is determined whether or not it is in the first state, that is, whether or not it is in the open/close execution mode (step S2206). If it is in the first state (step S2206: YES), the corresponding addition process of the counter for the first state is executed (step S2207). In the addition processing, the value of the counter corresponding to the value of the current check target counter among the first to fourteenth counters 142a to 142n for the first state in the first state area 142 of the history memory 117 is incremented by 1. .. For example, if the value of the confirmation target counter is “11”, the eleventh counter 142k for the first state is the addition target, and if the value of the confirmation target counter is “5”, the fifth counter 142e for the first state is the addition target. If the value of the confirmation target counter is "1", the first counter 142a for the first state is the addition target.

After that, by referring to the state information of the management side RAM 114, it is determined whether or not it is in the second state, that is, whether or not it is in the high frequency support mode (step S2208). If it is in the second state (step S2208: YES), the corresponding counter for the second state is added (step S2209). In the addition processing, one is added to the value of the counter corresponding to the current value of the check target counter among the first to fourteenth counters 143a to 143n for the second state in the second state area 143 of the history memory 117. .. For example, if the value of the check target counter is “11”, the eleventh counter 143k for the second state is the addition target, and if the value of the check target counter is “5”, the fifth counter 143e for the second state is the addition target. If the value of the check target counter is "1", the first counter 143a for the second state becomes the addition target.

After that, by referring to the state information of the management side RAM 114, it is determined whether or not it is in the third state, that is, whether or not the front door frame 14 is open (step S2210). If it is in the third state (step S2210: YES), the corresponding counter for the third state is added (step S2211). In the addition process, the value of the counter corresponding to the value of the current check target counter among the first to fourteenth counters 144a to 144n for the third state in the third state area 144 of the history memory 117 is incremented by 1. .. For example, if the value of the check target counter is “11”, the eleventh counter 144k for the third state is the addition target, and if the value of the check target counter is “5”, the fifth counter 144e for the third state is the addition target. If the value of the confirmation target counter is "1", the first counter 144a for the third state is the addition target.

When a negative determination is made in step S2204, a negative determination is made in step S2210, or when the processing of step S2211 is executed, the value of the check target counter of the management side RAM 114 is decremented by 1 (step S2212). Then, it is determined whether or not the value of the check target counter after the subtraction of 1 is "0" (step S2213). When the value of the check target counter is 1 or more (step S2213: NO), the process from step S2202 is executed for the check target corresponding to the new check target counter value.

By executing the history setting process as described above, the number of game balls entered into the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first working opening 33, and the second working opening 34, and the opening/closing execution The number of times the mode is generated, the number of times the high-frequency support mode is generated, and the number of times the game is generated are not stored as history information as in the first embodiment, but are stored as number-of-times information. This makes it possible to reduce the storage capacity required in the history memory 117, as compared with a configuration in which each history information is stored individually.

Since the number of times information is stored instead of the history information, it is not necessary to perform the process of deriving the number of times information from the history information when calculating various parameters. This makes it possible to reduce the processing load for calculating various parameters.

Next, the setting update recognition process in this embodiment executed by the management CPU 112 will be described with reference to the flowchart of FIG.

When the set value update signal input to the fifteenth buffer 122o of the input port 121 switches from the LOW level to the HI level (step S2301: YES), the value of the set value grasping counter in the management side RAM 114 is set to "1". It is set (step S2302). The set value grasping counter is a counter for the management side CPU 112 to specify the set value of the pachinko machine 10. For example, if the value of the set value grasping counter is "1", it means "setting 1", If the value of the setting value grasping counter is "6", it means "setting 6".

Then, it is determined whether or not the set value update signal input to the fifteenth buffer 122o of the input port 121 has switched from the LOW level to the HI level again (step S2303). If an affirmative decision is made in step S2303, the value of the set value grasping counter of the management side RAM 114 is incremented by 1 (step S2304). As a result, the set value of the pachinko machine 10 specified by the management-side CPU 112 is increased by one step.

When a negative determination is made in step S2303 or when the processing of step S2304 is executed, based on the input states of the first to eighth signals input to the first to eighth buffers 122a to 122h of the input port 121. Then, it is determined whether or not a setting value identification end command has been received from the main CPU 63 (step S2305). If a negative determination is made in step S2305, the process returns to step S2303.

If an affirmative decision is made in step S2305, a total eleventh counter 141k for measuring the number of times of game times executed in the total area 141 in the history memory 117, and an opening/closing execution in the total area 141 in the history memory 117 The eighth total counter 141h measuring the number of times of mode occurrence and the total ninth counter 141i measuring the number of occurrences of the high frequency support mode in the total area 141 of the history memory 117 are respectively provided. "0" is cleared (step S2306 to step S2308). As a result, the number of times the game is executed, the number of times the open/close execution mode is generated, and the number of times the high-frequency support mode is generated are all cleared to "0" when a new setting of the setting state of the pachinko machine 10 is performed. To be done. Therefore, the 31st parameter indicating the number of times of opening and closing execution mode per unit game time, the 41st parameter indicating the number of times of high frequency support mode per unit game time, and the high frequency support mode for the number of times of opening and closing execution mode The calculation result of the 42nd parameter indicating the ratio of the number of occurrences corresponds to the game content after the new setting of the setting state of the pachinko machine 10 is performed. In the configuration in which the winning probability of the jackpot result is changed when the setting value of the pachinko machine 10 is changed, the calculation results of the 31st parameter, the 41st parameter, and the 42nd parameter are set to the setting state of the pachinko machine 10 as described above. By making the contents corresponding to the game contents after the new setting is performed, the calculation results of the 31st parameter, the 41st parameter, and the 42nd parameter are appropriate based on the current setting value. It becomes possible to judge whether or not.

On the other hand, even if the setting state of the pachinko machine 10 is newly set, the counters other than the eighth total counter 141h, the total ninth counter 141i, and the eleventh counter 141k in the history memory 117 are " 0” is not cleared. As a result, the management of the number of game balls or the frequency of game balls entering each history-targeted ball input unit is performed based on the long-term game history without being affected by the new setting of the setting state of the pachinko machine 10. It becomes possible.

According to the above configuration, the number of game balls entered into the outlet 24a, the general prize opening 31, the special electric prize winning device 32, the first operation opening 33 and the second operation opening 34, the number of times the opening/closing execution mode has occurred, and high frequency support. The number of times the mode is generated and the number of times the game is generated are not stored as history information as in the first embodiment, but are stored as number information. This makes it possible to reduce the storage capacity required in the history memory 117, as compared with a configuration in which each history information is stored individually.

Further, since the number of pieces of information is stored as the number-of-times information instead of the history information, it is not necessary to perform the process of deriving the number-of-times information from the history information when calculating various parameters. This makes it possible to reduce the processing load for calculating various parameters.

Each piece of information on the number of times the game has been executed, the number of times the open/close execution mode has been generated, and the number of times the high-frequency support mode has been generated is cleared to "0" when a new setting of the setting state of the pachinko machine 10 is performed. Therefore, the 31st parameter indicating the number of times of opening and closing execution mode per unit game time, the 41st parameter indicating the number of times of high frequency support mode per unit game time, and the high frequency support mode for the number of times of opening and closing execution mode The calculation result of the 42nd parameter indicating the ratio of the number of occurrences corresponds to the game content after the new setting of the setting state of the pachinko machine 10 is performed. In the configuration in which the winning probability of the jackpot result is changed when the setting value of the pachinko machine 10 is changed, the calculation results of the 31st parameter, the 41st parameter, and the 42nd parameter are set to the setting state of the pachinko machine 10 as described above. By making the contents corresponding to the game contents after the new setting is performed, the calculation results of the 31st parameter, the 41st parameter, and the 42nd parameter are appropriate based on the current setting value. It becomes possible to judge whether or not.

On the other hand, even if the setting state of the pachinko machine 10 is newly set, the counters other than the eighth total counter 141h, the total ninth counter 141i, and the eleventh counter 141k in the history memory 117 are " 0” is not cleared. As a result, the management of the number of game balls or the frequency of game balls entering each history-targeted ball input unit is performed based on the long-term game history without being affected by the new setting of the setting state of the pachinko machine 10. It becomes possible.

Note that the configuration of the history memory 117 as in this embodiment may be applied to the first to fifth embodiments and the embodiments described after this embodiment. For example, when applied to the above-described first embodiment, the information in the history memory 117 is maintained as it is even if a new setting state of the pachinko machine 10 is set. Further, when applied to the third embodiment, when the setting state of the pachinko machine 10 is newly set, the entire history memory 117 is cleared to "0".

Further, the processing of step S2306 to step S2308 may be executed in the setting update recognition processing (FIG. 41) when the setting value of the pachinko machine 10 is changed. Thereby, even if a new setting of the setting state of the pachinko machine 10 is performed, if the set value is not changed before and after that, information on the number of times the game is executed, information on the number of times the open/close execution mode is generated, and high-frequency support The information of the number of times the mode is generated is not cleared to "0", and when the set value of the pachinko machine 10 is changed, the information of the number of times of the game time, the information of the number of times of the open/close execution mode, and the high frequency support mode It is possible to clear the information of the number of occurrences of “0”.

In addition, in the setting update recognition process (FIG. 41), various parameters are calculated using the counters 141 to 144 of the history memory 117 before the processes of steps S2306 to S2308 are executed, and the parameters are calculated. Various parameters may be stored in the calculation result memory 131.

<Seventh Embodiment>
In this embodiment, the structure of the history memory 117 is different from that of the first embodiment. The configuration different from that of the first embodiment will be described below. The description of the same configuration as that of the first embodiment is basically omitted.

FIG. 42 is an explanatory diagram for explaining the configuration of the history memory 117 in this embodiment.

As the history memory 117, history memories 181 to 186 corresponding to “setting 1” to “setting 6”, which are the setting states of the pachinko machine 10, are provided. Specifically, a history memory 181 for setting 1 is provided corresponding to "setting 1", and a history memory 182 for setting 2 is provided corresponding to "setting 2". A history memory 183 for setting 3 is provided corresponding to “setting 3”, a history memory 184 for setting 4 is provided corresponding to “setting 4”, and corresponding to “setting 5”. A history memory 185 for setting 5 is provided, and a history memory 186 for setting 6 is provided corresponding to “setting 6”.

Each of the history memories 181 to 186 for settings 1 to 6 is provided with a combination of the history area 124 and the pointer area 126 of the history memory 117 in the first embodiment. Thereby, it becomes possible to store the history information in association with each of the setting states of the pachinko machine 10 of “setting 1” to “setting 6”. In this case, when a new setting of the setting state of the pachinko machine 10 is performed, the history memories 181 to 186 corresponding to the set value for which the new setting is performed are the storage targets of the history information. It is possible to store the history information separately for each set value without erasing the history information when the setting state of the pachinko machine 10 is newly set. Further, since various parameters are calculated using the history information corresponding to the setting state of the pachinko machine 10 that is currently set, various parameters corresponding to each setting value can be appropriately derived.

In addition, in each of the history memories 181 to 186 for the settings 1 to 6, the total area 141, the first state area 142, the second state area 143, and the third state area 144 in the sixth embodiment are provided. The combination may be set.

Next, the setting update recognition process in this embodiment executed by the management CPU 112 will be described with reference to the flowchart in FIG.

When the set value update signal input to the fifteenth buffer 122o of the input port 121 switches from the LOW level to the HI level (step S2401: YES), the value of the set value grasping counter provided in the calculation result memory 131 Is set to "1" (step S2402). The set value grasping counter is a counter for the management side CPU 112 to specify the set value of the pachinko machine 10. For example, if the value of the set value grasping counter is "1", it means "setting 1", If the value of the setting value grasping counter is "6", it means "setting 6". Further, in the present embodiment, the setting value grasping counter is provided in the operation result memory 131, which is a memory that does not require external power supply for storing and holding, and therefore it is assumed that the supply of operating power to the management IC 66 is stopped. Also, the value stored in the set value grasping counter is stored and retained.

After that, it is determined whether or not the setting value update signal input to the fifteenth buffer 122o of the input port 121 has switched from the LOW level to the HI level again (step S2403). When an affirmative determination is made in step S2403, the value of the set value grasping counter of the calculation result memory 131 is incremented by 1 (step S2404). As a result, the set value of the pachinko machine 10 specified by the management-side CPU 112 is increased by one step.

When a negative determination is made in step S2403 or when the processing of step S2404 is executed, based on the input states of the first to eighth signals input to the first to eighth buffers 122a to 122h of the input port 121. Then, it is determined whether or not a setting value identification end command has been received from the main CPU 63 (step S2405). When a negative determination is made in step S2405, the process returns to step S2403.

When an affirmative determination is made in step S2405, the history memories 181 to 186 corresponding to the values of the set value grasping counter of the calculation result memory 131 are set as the storage target of the history information and the reference target when the various parameters are calculated ( Step S2406). Specifically, if the value of the set value grasping counter is “1”, it means that the setting is set to “setting 1”. Therefore, the history memory 181 for setting 1 is set to the storage target of history information and various parameters. Set as a reference target during calculation. Further, if the value of the set value grasping counter is "2", it means that the setting is set to "setting 2". Therefore, the history memory 182 for setting 2 is used for storing the history information and when calculating various parameters. Set as a reference target. Further, if the value of the set value grasping counter is “3”, it means that the setting is set to “setting 3”. Therefore, the history memory 183 for setting 3 is set in the history information storage target and when various parameters are calculated. Set as a reference target. Further, if the value of the set value grasping counter is “4”, it means that the setting is set to “setting 4”. Therefore, the history memory 184 for setting 4 is used for storing the history information and calculating various parameters. Set as a reference target. Further, if the value of the set value grasping counter is "5", it means that the setting is set to "setting 5". Therefore, the history memory 185 for setting 5 is used for storing the history information and calculating various parameters. Set as a reference target. Further, if the value of the set value grasping counter is “6”, it means that the setting is set to “setting 6”. Therefore, the history memory 186 for setting 6 is set in the history information storage target and when various parameters are calculated. Set as a reference target.

After that, the RTC information which is the date information and the time information is read from the RTC 115 (step S2407). Then, the writing process to the history memory 117 is executed (step S2408). In the writing process, the history memories 181 to 186 set as the storage targets of the history information in step S2406 are selected from the history memories 181 to 186 for the settings 1 to 6. Then, by referring to the pointer area 126 in the history memories 181 to 186 which are the storage objects, the pointer information of the history area 124 which is the current writing object is specified and becomes the writing object. The RTC information read in step S2407 is written to the history information storage area 125 of the history area 124 corresponding to the pointer information. Further, the information for identifying the set value is written in the history information storage area 125 corresponding to the pointer information to be written. As a result, a combination of the information indicating that the setting state of the pachinko machine 10 is newly set and the RTC information corresponding to the date and time when the setting is performed is stored as history information.

After that, the update processing of the target pointer is executed (step S2409). In the update processing, the history memories 181 to 186 set as the storage targets of history information in step S2406 are selected from the history memories 181 to 186 for the settings 1 to 6, and the history memories 181 to 186 are selected. The numerical information stored in the pointer area 126 is read and 1 is added. It is determined whether or not the pointer information after the addition of 1 exceeds the maximum value of the pointer information in the history area 124. If the maximum value is not exceeded, the pointer information after adding 1 is overwritten in the pointer area 126 as new pointer information to be written. If the maximum value is exceeded, the pointer area 126 is cleared to "0" so that the pointer information to be written becomes the first pointer information.

According to the above configuration, as the history memory 117, the history memories 181 to 186 for the settings 1 to 6 are provided so as to correspond to the “setting 1” to the “setting 6”, respectively. As a result, it becomes possible to store the game history in correspondence with each of the setting states of the pachinko machine 10 of "setting 1" to "setting 6". In this case, when a new setting of the setting state of the pachinko machine 10 is performed, the history memories 181 to 186 corresponding to the set value for which the new setting is performed are the storage targets of the history information. It is possible to store the history information separately for each set value without erasing the history information when the setting state of the pachinko machine 10 is newly set. Further, since various parameters are calculated using the history information corresponding to the setting state of the pachinko machine 10 that is currently set, various parameters corresponding to each setting value can be appropriately derived.

Note that the history memory 117 is not limited to the configuration in which the six history memories 181 to 186 for the settings 1 to 6 are provided, and one memory can be used for the setting 1 Corresponding to the history memory 181 for setting 2, an area corresponding to the history memory 182 for setting 2, an area corresponding to the history memory 183 for setting 3, and a history memory 184 for setting 4. An area, an area corresponding to the history memory 185 for setting 5, and an area corresponding to the history memory 186 for setting 6 may be set.

<Eighth Embodiment>
In this embodiment, the structure of the history memory 117 is different from that of the first embodiment. The configuration different from that of the first embodiment will be described below. The description of the same configuration as that of the first embodiment is basically omitted.

FIG. 44 is an explanatory diagram for explaining the configuration of the history memory 117 in this embodiment.

As the history memory 117, a first history memory 191 and a second history memory 192 are provided. Each of the first history memory 191 and the second history memory 192 is provided with a combination of the history area 124 and the pointer area 126 of the history memory 117 in the first embodiment. In this case, when the history information is stored using one of the history memories 191 and 192 of the first history memory 191 and the second history memory 192, the setting state of the pachinko machine 10 is newly set. If a certain number of pieces of history information are stored in the other history memories 191 and 192, the history information of the one history memory 191 and 192 is not erased and remains. In addition, it is possible to store history information newly in both history memories 191 and 192 until a predetermined number or more of history information is stored in the other history memories 191 and 192. Become.

Next, the setting update recognition processing in this embodiment executed by the management CPU 112 will be described with reference to the flowchart in FIG.

When the set value update signal input to the fifteenth buffer 122o of the input port 121 switches from the LOW level to the HI level (step S2501: YES), the value of the set value grasping counter provided in the management side RAM 114 is set to " 1” (step S2502). The set value grasping counter is a counter for the management side CPU 112 to specify the set value of the pachinko machine 10. For example, if the value of the set value grasping counter is "1", it means "setting 1", If the value of the setting value grasping counter is "6", it means "setting 6".

Then, it is determined whether or not the set value update signal input to the fifteenth buffer 122o of the input port 121 has switched from the LOW level to the HI level again (step S2503). When an affirmative determination is made in step S2503, the value of the set value grasping counter in the management side RAM 114 is incremented by 1 (step S2504). As a result, the set value of the pachinko machine 10 specified by the management-side CPU 112 is increased by one step.

If a negative determination is made in step S2503, or if the processing of step S2504 is executed, based on the input states of the first to eighth signals input to the first to eighth buffers 122a to 122h of the input port 121. Then, it is determined whether or not a setting value identification end command has been received from the main CPU 63 (step S2505). When a negative determination is made in step S2505, the process returns to step S2503.

When a positive determination is made in step S2505, "1" is set to the setting change occurrence flag provided in the calculation result memory 131 (step S2506). The setting change occurrence flag has been set as a storage target of history information until then in the first history memory 191 and the second history memory 192 after a new setting of the setting state of the pachinko machine 10 is performed. This is a flag for the management CPU 112 to specify whether not only the history memories 191 and 192 but also the other history memories 191 and 192 are the storage targets of the history information. Further, since the setting change occurrence flag is provided in the operation result memory 131, which is a memory that does not require external power supply for storing and holding, even if supply of operating power to the management IC 66 is stopped, setting change occurs. The value stored in the flag is stored and retained.

After that, the RTC information which is the date information and the time information is read from the RTC 115 (step S2507). Then, the writing process to the history memories 191 and 192 is executed (step S2508). In the writing process, first, the pointer area 126 of the first history memory 191 is referenced to specify the pointer information of the history area 124 that is the current writing target, and the pointer information of the writing target is specified. The RTC information read in step S2507 is written in the history information storage area 125 of the history area 124 corresponding to. Further, both the information for identifying the set value and the value information of the set value grasping counter are written in the history information storage area 125 corresponding to the pointer information to be written. Thereby, the information indicating that the setting state of the pachinko machine 10 is newly set, the RTC information corresponding to the date and time when the setting is performed, and the information of the setting value when the setting is performed, The combination is stored as history information in the first history memory 191. In the writing process, the pointer information 126 of the history area 124 that is the current writing target is specified by referring to the pointer area 126 of the second history memory 192, and the pointer that is the writing target is specified. The RTC information read in step S2507 is written in the history information storage area 125 of the history area 124 corresponding to the information. Further, both the information for identifying the set value and the value information of the set value grasping counter are written in the history information storage area 125 corresponding to the pointer information to be written. Thereby, the information indicating that the setting state of the pachinko machine 10 is newly set, the RTC information corresponding to the date and time when the setting is performed, and the information of the setting value when the setting is performed, The combination is stored in the second history memory 192 as history information.

After that, update processing of each target pointer is executed (step S2509). In the update process, first, the numerical information stored in the pointer area 126 of the first history memory 191 is read and 1 is added. It is determined whether or not the pointer information after the addition of 1 exceeds the maximum value of the pointer information in the history area 124. If the maximum value is not exceeded, the pointer information after adding 1 is overwritten in the pointer area 126 as new pointer information to be written. If the maximum value is exceeded, the pointer area 126 is cleared to "0" so that the pointer information to be written becomes the first pointer information. In the update process, the numerical information stored in the pointer area 126 of the second history memory 192 is read and 1 is added. It is determined whether or not the pointer information after the addition of 1 exceeds the maximum value of the pointer information in the history area 124. If the maximum value is not exceeded, the pointer information after adding 1 is overwritten in the pointer area 126 as new pointer information to be written. If the maximum value is exceeded, the pointer area 126 is cleared to "0" so that the pointer information to be written becomes the first pointer information.

Next, the history setting process in this embodiment executed by the management CPU 112 will be described with reference to the flowchart of FIG.

When "1" is not set in the setting change occurrence flag of the calculation result memory 131 (step S2601: NO), the side of the first history memory 191 and the second history memory 192 that is the storage target is selected. This means that only the history information should be stored. In this case, first, the history memories 191 and 192 that are currently stored are grasped (step S2602). The calculation result memory 131 is provided with a storage target flag. When the value of the storage target flag is “0”, the first history memory 191 is the storage target, and the value of the storage target flag is “1”. If it is, the second history memory 192 is to be stored. Since the storage target flag is provided in the operation result memory 131, which is a memory that does not require external power supply for storing and holding, even if the supply of operating power to the management IC 66 is stopped, the storage target flag is stored. The value of is stored and retained.

After that, the history setting execution process is executed for the history memories 191 and 192 that are the storage targets (step S2603). Specifically, the processes of steps S1101 to S1112 of the history setting process (FIG. 26) in the first embodiment are executed for one of the history memories 191 and 192 that are storage targets. As a result, the history information is stored in one of the history memories 191 and 192 that are storage targets.

On the other hand, when “1” is set in the setting change occurrence flag of the calculation result memory 131 (step S2601: YES), it is a storage target of the first history memory 191 and the second history memory 192. This means that the history information should be stored not only on the side but also on the other side. In this case, history setting execution processing is executed for both history memories 191 and 192 (step S2604). Specifically, first, the processes of steps S1101 to S1112 of the history setting process (FIG. 26) in the first embodiment are executed on the first history memory 191. As a result, the history information is stored in the first history memory 191. After that, the processes of steps S1101 to S1112 of the history setting process (FIG. 26) in the first embodiment are executed on the second history memory 192. As a result, the history information is stored in the second history memory 192.

When the process of step S2603 is executed or the process of step S2604 is executed, it is determined whether "1" is set in the setting change occurrence flag of the calculation result memory 131 (step S2605). When an affirmative determination is made in step S2605, it is determined whether or not there is a predetermined number or more of ball discharge histories in the history memories 191, 192 that are not to be stored (step S2606). Specifically, when the value of the storage target flag of the calculation result memory 131 is “0”, the first history memory 191 is the storage target, so the game area PA is stored in the second history memory 192. It is determined whether or not a predetermined number (specifically, "1000") of history information indicating that the game balls have been discharged is stored. Further, when the value of the storage target flag of the calculation result memory 131 is “1”, the second history memory 192 is the storage target, so the first history memory 191 is moved from the game area PA to the game ball. It is determined whether or not a predetermined number (specifically, “1000”) of history information indicating that the has been discharged is stored. It should be noted that the game time is executed rather than determining whether or not a predetermined number (specifically, “1000”) of history information indicating that the game balls have been discharged from the game area PA is stored. It may be configured to determine whether or not a predetermined number (specifically, “100”) or more of history information indicating is stored.

When an affirmative determination is made in step S2606, a storage target change process is executed (step S2607). In the change processing of the storage object, the value of the storage object flag of the operation result memory 131 is set to a value different from the current value between the two values, whereby the first history memory 191 and the second history memory 192 are set. The side to be memorized is changed. Specifically, if the value of the storage target flag is “0”, the storage target is changed from the first history memory 191 to the second history memory 192 by setting the storage target flag to “1”. If the value of the storage target flag is “1”, the storage target is changed from the second history memory 192 to the first history memory 191 by clearing the storage target flag “0”. As a result, the history memories 191 and 192 in which only the history information of the game executed after the new setting of the setting state of the pachinko machine 10 is stored are set as storage targets. Then, various parameters are calculated by using the history information of the history memories 191 and 192 which are newly stored, so that it is executed after the new setting of the setting state of the pachinko machine 10 is performed. It is possible to derive various parameters depending on the game.

After that, the clear process is executed on the side of the first history memory 191 and the second history memory 192 that has been the storage target until then (step S2608). Specifically, if the value of the storage target flag is "0", the second history memory 192 is cleared to "0", and if the value of the storage target flag is "1", the first history memory 191 is " 0” is cleared. After that, the setting change occurrence flag of the calculation result memory 131 is cleared to "0" (step S2609).

Next, the display output processing in this embodiment executed by the management CPU 112 will be described with reference to the flowchart of FIG.

If it is the calculation timing (step S2701: YES), the storage target side of the first history memory 191 and the second history memory 192 is grasped (step S2702). Specifically, if the value of the storage target flag of the operation result memory 131 is “0”, the first history memory 191 is grasped as the storage target, and if the value of the storage target flag is “1”, the second history memory 191 is stored. The history memory 192 is grasped as a storage target. After that, using the history information stored in the storage target history memories 191 and 192 grasped in step S2702, steps S1402 to S1412 of the display output process (FIG. 30) in the first embodiment are executed. By doing so, various parameters (first to eighth parameters, eleventh to eighteenth parameters, twenty-first to twenty-sixth parameters, thirty-first parameters, fourteenth to forty-second parameters) are calculated, and the calculated various parameters are calculated. The result memory 131 is stored (step S2703). In this case, the history information is stored in both the first history memory 191 and the second history memory 192 because "1" is set in the setting change occurrence flag of the calculation result memory 131. Even if there is, various parameters are calculated using one of the history memories 191 and 192 that are storage targets.

If a negative determination is made in step S2701, or if the process of step S2703 has been executed, the display process is executed (step S2704). The processing content of the display processing is the same as the display processing (FIG. 31) in the first embodiment.

According to the above configuration, the first history memory 191 and the second history memory 192 are provided as the history memory 117, and when a new setting of the setting state of the pachinko machine 10 is performed, While the history memories 191 and 192 that have been storage targets are directly stored, the history information is also stored in the history memories 191 and 192 that are not storage targets. When a predetermined number or more of history information corresponding to the discharge of the game balls from the game area PA is stored in the history memories 191 and 192 on the side that is not the storage target, it is not the storage target. The history memories 191 and 192 on the side are stored as they are, and the history memories 191 and 192 on the side that have been stored until then are cleared to “0”. Thereby, when a new setting of the setting state of the pachinko machine 10 is performed, it is possible to calculate various parameters using only history information of the game performed at the newly set setting value. Become.

On the other hand, according to the above configuration, even if a new setting of the setting state of the pachinko machine 10 is repeatedly performed in a short period of time so as not to appropriately calculate various parameters, the history target to be stored is stored. Memories 191 and 192 remain unchanged. Thereby, even if a new setting of the setting state of the pachinko machine 10 is repeatedly performed in a short period of time, it is possible to appropriately derive the management result of the game history up to that point.

It should be noted that the history memory 117 is not limited to a configuration in which two memories, a first history memory 191 and a second history memory 192, are provided, and one memory can be used for the first history. The first history area corresponding to the second memory 191 and the second history area corresponding to the second history memory 192 may be set.

Alternatively, only one history memory 117 may be provided. In this case, when the total number of game balls discharged from the game area PA becomes equal to or more than a predetermined number after the new setting of the pachinko machine 10 is performed, the new setting of the pachinko machine 10 is performed. The history information before the specified timing may be deleted, and the history information after the setting timing may be stored and retained without being deleted. As a result, at a timing when a predetermined number or more of history information is accumulated after the new setting of the setting state of the pachinko machine 10 is performed, the history before the timing when the new setting of the setting state of the pachinko machine 10 is performed. It becomes possible to erase information. In addition, the history information corresponding to the new setting state of the pachinko machine 10 is stored in the history memory 117 at the timing when the new setting state of the pachinko machine 10 is set. It is possible to distinguish the history information before and the history information after the timing.

Further, the timing of deleting the history information is not limited to the case where the total number of discharged game balls from the game area PA becomes a predetermined number or more after the new setting of the setting state of the pachinko machine 10 is performed. Instead, the number of game times executed after the new setting of the setting state of the pachinko machine 10 is performed may be a predetermined number or more.

Further, even if a new setting of the setting state of the pachinko machine 10 is performed and the setting value is not changed before and after the new setting, the change of the history memories 191 and 192 to be stored and the history information When the new setting of the setting state of the pachinko machine 10 is performed without erasing, and when the set value is changed before and after that, the history memories 191 and 192 to be stored as described above. May be changed and the history information may be deleted.

<Ninth Embodiment>
In the present embodiment, among the first to sixteenth buffers 122a to 122p of the input port 121 in the management-side I/F 111, the type of the signal whose input signal is determined in the design stage of the management IC 66 is the above-mentioned. This is different from the first embodiment. Further, the processing configuration executed by the main CPU 63 in order to specify the type of the input signal to the management CPU 112 is different from that of the first embodiment. The configuration different from that of the first embodiment will be described below. The description of the same configuration as that of the first embodiment is basically omitted.

FIG. 48 is an explanatory diagram for explaining the configuration of the input port 121 of the management-side I/F 111 in this embodiment.

The same kind of signal as that of the first embodiment is input to the first to seventh buffers 122a to 122g and the 16th buffer 122p. Specifically, the first signal corresponding to the detection result of the first winning opening detection sensor 42a is input to the first buffer 122a, and the first signal corresponding to the detection result of the second winning opening detection sensor 43a is input to the second buffer 122b. Two signals are input, a third signal corresponding to the detection result of the third winning a prize mouth detection sensor 44a is input to the third buffer 122c, and a fourth signal corresponding to the detection result of the special electric power detection sensor 45a is input to the fourth buffer 122d. A signal is input, a fifth signal corresponding to the detection result of the first working port detection sensor 46a is input to the fifth buffer 122e, and a sixth signal corresponding to the detection result of the second working port detection sensor 47a is input to the sixth buffer 122f. The sixth signal is input, the seventh signal corresponding to the detection result of the outlet detection sensor 48a is input to the seventh buffer 122g, and the output instruction signal is input to the sixteenth buffer 122p.

On the other hand, in the first embodiment, the signal corresponding to the open/close execution mode is input to the eighth buffer 122h as the eighth signal, and the signal corresponding to the high frequency support mode is input to the ninth buffer 122i as the ninth signal, A signal corresponding to the front door frame 14 is input to the tenth buffer 122j as the tenth signal, a signal corresponding to the start of the game game is input to the eleventh buffer 122k as the eleventh signal, and the set value update signal is the fifteenth buffer. However, in the present embodiment, the buffers to which these signals are input are different. Specifically, the signal corresponding to the start of the game round is input to the eleventh buffer 122k as the game round signal, the set value update signal is input to the twelfth buffer 122l, and the signal corresponding to the open/close execution mode is in the open/close execution mode. The signal corresponding to the high frequency support mode is input to the thirteenth buffer 122m as a signal, the signal corresponding to the high frequency support mode is input to the fourteenth buffer 122n, and the signal corresponding to the front door frame 14 is the fifteenth door opening signal. It is input to the buffer 122o.

The game time signal is input to the eleventh buffer 122k, the set value update signal is input to the twelfth buffer 122l, the open/close execution mode signal is input to the thirteenth buffer 122m, and the fourteenth buffer 122n. It is determined at the design stage of the management IC 66 that the high frequency support mode input signal is input, the fifteenth buffer 122o is input with the door opening signal, and the sixteenth buffer 122p is input with an output instruction signal. Therefore, without receiving an instruction from the main CPU 63, the management CPU 112 can specify that the respective signals corresponding to the 11th to 16th buffers 122k to 122p are input. On the other hand, what kind of signal is input to the first to tenth buffers 122a to 122j has not been determined in the design stage of the management IC 66, and these kinds of signals are instructed by the main CPU 63. As a result, the CPU 112 on the management side specifies. The process for specifying the type of the signal is executed when the supply of the operating power to the main CPU 63 and the management CPU 112 is started, as in the first embodiment.

FIG. 49 is a flowchart showing the recognition processing of this embodiment executed by the main CPU 63. The recognition process is executed in step S111 in the main process (FIG. 9) as in the first embodiment.

First, "10", which is the number of the first to tenth buffers 122a to 122j to be recognized for the signal type, is set in the recognition output counter of the main RAM 65 (step S2801). After that, the output processing of the identification start signal is executed (step S2802). In the output process, the output states of the first signal input to the first buffer 122a, the open/close execution mode signal input to the thirteenth buffer 122m, and the high frequency support mode input signal input to the fourteenth buffer 122n. Is set to the HI level, the output of the identification start signal is started. The period in which these signals are maintained at the HI level is set to a period sufficient for the management side CPU 112 to recognize the output state of these signals.

After that, the information on the output count corresponding to the current value of the recognition output counter of the main RAM 65 is read from the main ROM 64, and the read output count information is set in the output counter provided in the main RAM 65 ( Step S2803). The output number counter is a counter for the main CPU 63 to specify the output number of the type identification signal.

In the present embodiment, when the management-side CPU 112 recognizes the types of signals input to the first buffer 122a to the tenth buffer 122j, the number of prize balls set for the incoming ball portion corresponding to the signal type. And the type identification signal is output the same number of times as. The management side CPU 112 stores information corresponding to the number of times the type identification signal is received for each of the first buffer 122a to the tenth buffer 122j in the first to tenth correspondence area 123a to 123j of the correspondence memory 116. .. That is, the type of the signal input to the first buffer 122a to the tenth buffer 122j is grasped as the number of prize balls set for the ball entering portion corresponding to the type of the signal.

In step S2803, when the value of the recognition output counter is any of "10", "9" and "8", "10" corresponding to the number of prize balls of the general winning opening 31 is set in the output number counter. .. Further, when the value of the recognition output counter is "7", "15" corresponding to the number of prize balls of the special electric winning device 32 is set in the output number counter. Further, when the value of the recognition output counter is "6", "1" corresponding to the number of prize balls of the first operating port 33 is set in the output number counter. Further, when the value of the recognition output counter is "5", "1" corresponding to the number of prize balls of the second operating port 34 is set in the output number counter. When the value of the output counter for recognition is “4”, the payout of the game ball is not executed even though the game ball enters the out port 24a although it corresponds to the out port 24a. Therefore, the output number counter Set "0" to. Further, when the value of the recognition output counter is any one of "3" to "1", since the corresponding ball entry portion does not exist and is blank, "0" is set in the output number counter.

After that, the output process of the start trigger signal is executed (step S2804). In the output process, the output of the start trigger signal is started by setting the output state of the first signal input to the first buffer 122a to the HI level. The period during which the first signal is maintained at the HI level is set to a period sufficient for the management-side CPU 112 to recognize the output state of the first signal.

After that, on the condition that the value of the output counter of the main RAM 65 is not "0" (step S2805: YES), that is, on the condition that a value of 1 or more is set on the output counter in step S2803, The process advances to step S2806. In step S2806, a type identification signal output process is executed. In the output process, the output state of the type identification signal is started by setting the output state of the second signal input to the second buffer 122b to the HI level. The period in which the second signal is maintained at the HI level is set to a period sufficient for the management-side CPU 112 to recognize the output state of the second signal.

Then, the value of the output counter of the main RAM 65 is decremented by 1 (step S2807), and it is determined whether the value of the output counter after decrementing by 1 is "0" (step S2808). When the value of the output counter is 1 or more (step S2808: NO), the process returns to step S2806.

If an affirmative decision is made in step S2805, or if an affirmative decision is made in step S2808, the termination trigger signal output processing is executed (step S2809). In the output process, the output of the termination trigger signal is started by setting the output state of the third signal input to the third buffer 122c to the HI level. The period in which the third signal is maintained at the HI level is set to a period sufficient for the management-side CPU 112 to recognize the output state of the third signal.

After that, the value of the recognition output counter of the main RAM 65 is decremented by 1 (step S2810), and it is determined whether the value of the recognition output counter after the decrement by 1 is "0" (step S2811). When the value of the recognition output counter is 1 or more (step S2811: NO), the process returns to step S2803, and processing for recognizing the type of signal corresponding to the value of the recognition output counter after subtraction by 1 is executed. To do.

On the other hand, when the value of the recognition output counter is "0" (step S2811: YES), the output processing of the identification end signal is executed (step S2812). In the output process, output states of the third signal input to the third buffer 122c, the open/close execution mode signal input to the thirteenth buffer 122m, and the high-frequency support mode input signal input to the fourteenth buffer 122n. Is set to the HI level, the output of the identification end signal is started. The period in which these signals are maintained at the HI level is set to a period sufficient for the management side CPU 112 to recognize the output state of these signals.

Next, the management processing executed in the management CPU 112 according to this embodiment will be described with reference to the flowchart of FIG. The management process is started when the supply of the operating power to the management-side CPU 112 is started as in the first embodiment.

First, it is determined whether or not the reception of the identification start signal from the main CPU 63 is completed (step S2901). If the identification start signal has not been received, the setting update recognition process is executed in step S2902, and then the process of step S2901 is executed again. The processing content of the setting update recognition processing is the same as that of the first embodiment.

When the reception of the identification start signal from the main CPU 63 is completed (step S2901: YES), the value of the setting target counter of the management RAM 114 is cleared to "0" (step S2903). After that, on condition that the start trigger signal is received from the main CPU 63 (step S2904: YES), the process proceeds to step S2905. In step S2905, it is determined whether the type identification signal is received from the main CPU 63. When the type identification signal is received (step S2905: YES), the value of the reception number counter provided in the management side RAM 114 is incremented by 1 (step S2906). The reception counter is a counter for the management CPU 112 to specify the number of times the type identification signal has been received from the main CPU 63. The value of the reception number counter is cleared to "0" when a positive determination is made in step S2904.

When a negative determination is made in step S2905 or when the processing of step S2906 is executed, it is determined whether or not an end trigger signal is received from the main CPU 63 (step S2907). If the termination trigger signal has not been received (step S2907: NO), the process returns to step S2905, and if the termination trigger signal has been received (step S2907: YES), the correspondence setting process is executed (step S2908). In the correspondence relation setting process, among the first to tenth correspondence relation areas 123a to 123j of the correspondence relation memory 116, the correspondence relation area corresponding to the current value in the setting target counter of the management side RAM 114 is set in the reception number counter. Stores the value that is set. In this case, “10” corresponding to the number of prize balls of the general winning opening 31 is set in the first correspondence area 123a, the second correspondence area 123b, and the third correspondence area 123c, and the fourth correspondence area 123d is set. Is set to "15" corresponding to the number of prize balls of the special electric prize winning device 32, "1" corresponding to the number of prize balls of the first working port 33 is set to the fifth correspondence area 123e, and the sixth correspondence relationship In the area 123f, "1" corresponding to the number of prize balls of the second working port 34 is set. Also, "0" is set in the seventh to twelfth correspondence areas 123g to 123l. After that, the value of the setting target counter of the management RAM 114 is incremented by 1 (step S2909).

When a negative determination is made in step S2904 or when the processing of step S2909 is executed, it is determined whether or not the reception of the identification end signal from the main CPU 63 is completed (step S2910). When the reception of the identification end signal is not completed (step S2910: NO), the process returns to step S2904, and on condition that the start trigger signal is received from the main CPU 63 (step S2904: YES), the processes after step S2905 are performed. Execute. When the reception of the identification end signal from the main CPU 63 is finished (step S2910: YES), the history setting process of step S2911, the display output process of step S2912, and the external output process of step S2913 are repeatedly executed.

FIG. 51 is a time chart showing a state in which information on the correspondence between the first to tenth buffers 122a to 122j and the types of signals input to these buffers 122a to 122j is stored in the correspondence memory 116. 51(a) shows a period in which the output state of the first signal is at the HI level, FIG. 51(b) shows a period in which the output state of the second signal is at the HI level, and FIG. ) Indicates a period during which the output state of the third signal is at the HI level, FIG. 51(d) indicates a period during which the output state of the signal in the open/close execution mode is at the HI level, and FIG. FIG. 51(f) shows the first to tenth buffers 122a to 122j and the types of signals input to these buffers 122a to 122j, showing the period during which the output state of the signal in the high frequency support mode is at the HI level. 51G shows the execution period of the identification state in which the process for identifying the correspondence is executed, FIG. 51G shows the timing when the value of the reception counter of the management side RAM 114 is incremented by 1, and FIG. The timing at which the management CPU 112 executes the correspondence setting process (step S2908) is shown.

As the supply of the operating power to the main CPU 63 and the management CPU 112 is started, at the timing of t1, as shown in FIGS. 51(a), 51(d) and 51(e), the first signal The output states of the open/close execution mode signal and the high-frequency support mode signal are changed from the LOW level to the HI level. As a result, the output of the identification start signal from the main CPU 63 to the management CPU 112 is started. Then, at the timing of t2, the output states of the first signal, the open/close execution mode signal, and the high-frequency support mode signal are changed from the HI level to the LOW bell. As a result, the output of the identification start signal from the main CPU 63 to the management CPU 112 is stopped. At the timing of t2, the management-side CPU 112 makes an affirmative decision in step S2901 of the management processing (FIG. 50), and the identification state is entered as shown in FIG. 51(f).

After that, the output state of the first signal is maintained at the HI level from timing t3 to timing t4 as shown in FIG. As a result, the start trigger signal is output to the management-side CPU 112. Then, from the timing of t5 to the timing of t7, the output state of the second signal is maintained at the HI level as shown in FIG. 51(b). As a result, the type identification signal is output to the management-side CPU 112 once. In this case, the value of the reception number counter of the management RAM 114 is incremented by 1 at the timing of t6 as shown in FIG.

After that, from the timing t8 to the timing t10, the output state of the third signal is maintained at the HI level as shown in FIG. 51(c). As a result, the termination trigger signal is output to the management-side CPU 112. In this case, at the timing of t9, the management side CPU 112 executes the correspondence setting process as shown in FIG. Since the value of the reception number counter is "1" at the timing when the correspondence relation setting process is executed, the correspondence relation information "1" is stored in the correspondence relation memory 123 in the correspondence relation memory 116 as the correspondence relation information 123a to 123j. Information is stored.

After that, from the timing of t11 to the timing of t12, the output state of the first signal is maintained at the HI level as shown in FIG. As a result, the start trigger signal is output to the management-side CPU 112. Then, as shown in FIG. 51( b ), the timing t13 to timing t15, the timing t16 to timing t18, the timing t19 to timing t21, and the timing t22 to timing t24 are changed as shown in FIG. The output state of the signal is maintained at the HI level. As a result, the type identification signal is output to the management-side CPU 112 once. In this case, the value of the reception number counter of the management side RAM 114 is incremented by 1 as shown in FIG. 51(g) at each of the timing t14, the timing t17, the timing t20, and the timing t23.

After that, from the timing of t25 to the timing of t27, the output state of the third signal is maintained at the HI level as shown in FIG. 51(c). As a result, the termination trigger signal is output to the management-side CPU 112. In this case, at the timing of t26, as shown in FIG. 51(h), the management side CPU 112 executes the correspondence setting process. Since the value of the reception number counter is “10” at the timing when the correspondence relation setting process is executed, the correspondence relation information “10” is stored in the correspondence relation memory 123 in the correspondence relation memory 116 as the correspondence relation information 123a to 123j. Information is stored.

After that, at the timing of t28, as shown in FIGS. 51C, 51D, and 51E, the output states of the third signal, the open/close execution mode signal, and the high-frequency support mode signal are LOW. Level is changed to HI level. As a result, the output of the identification end signal from the main CPU 63 to the management CPU 112 is started. Then, at the timing of t29, the output states of the third signal, the open/close execution mode signal, and the high-frequency support mode signal are changed from the HI level to the LOW bell. As a result, the output of the identification end signal from the main CPU 63 to the management CPU 112 is stopped. At the timing of t29, the management-side CPU 112 makes an affirmative decision in step S2910 of the management processing (FIG. 50), so that the identification state is canceled as shown in FIG. 51(f).

Note that, in the present embodiment, since information on the number of prize balls is stored as the correspondence information, the history information stored in the history memory 117 is stored in the history information, and the prize balls corresponding to the ball-entering portion that triggered the storage of the history information. Information on the number of pieces is included as correspondence information. In this configuration, when there are a plurality of types of ball entrances having the same number of prize balls, the ball entrances cannot be distinguished in the history information. Specifically, since the number of prize balls for each of the first operating port 33 and the second operating port 34 is one, it is possible to distinguish the first operating port 33 and the second operating port 34 in the history information. Can not. In such a situation, the number of prize balls of the first operating port 33 and the second operating port 34 may be different. This makes it possible to distinguish the first operation port 33 and the second operation port 34 in the history information even with the configuration in which the history information is stored as in the present embodiment.

According to the present embodiment described in detail above, not only the set value update signal and the output instruction signal, but also information corresponding to whether or not the game time is started, information corresponding to whether or not in the opening and closing execution mode, Regarding the information corresponding to whether or not the high frequency support mode is in progress and the information corresponding to whether or not the front door frame 14 is in the open state, the main CPU 63 determines that the signal path corresponds to these information. It is possible for the management-side CPU 112 to specify the correspondence relationship information without receiving the correspondence information. In this case, only the information corresponding to the detection result of each of the ball entrance detection sensors 42a to 48a is the information required to cause the management CPU 112 to recognize the correspondence between each information and each signal path 118a to 118j. Become. When causing the management-side CPU 112 to recognize the correspondence information, the same number of pulse signals as the number of prize balls corresponding to each of the ball detection sensors 42a to 48a are transmitted from the main-side CPU 63 to the management-side CPU 112 using the second signal. Is output to. This makes it possible to simplify the configuration related to the transmission of the correspondence information.

<Tenth Embodiment>
The present embodiment is different from the first embodiment in the configuration for providing the information of each entrance result to the management IC 66. The configuration different from that of the first embodiment will be described below. The description of the same configuration as that of the first embodiment is basically omitted.

FIG. 52 is an explanatory diagram for explaining a configuration of a signal path for allowing the detection results of the ball detection sensors 42a to 48a to be input to the main CPU 63 and the management IC 66.

The detection result of the first winning opening detection sensor 42a is input to the main CPU 63 through the first signal path SL11. The detection result of the second winning opening detection sensor 43a is input to the main CPU 63 through the second signal path SL12. The detection result of the third winning opening detection sensor 44a is input to the main CPU 63 through the third signal path SL13. The detection result of the special electric power detection sensor 45a is input to the main CPU 63 through the fourth signal path SL14. Further, the detection result of the first working port detection sensor 46a is input to the main CPU 63 through the fifth signal path SL15. The detection result of the second working port detection sensor 47a is input to the main CPU 63 through the sixth signal path SL16. The detection result of the outlet detection sensor 48a is input to the main CPU 63 through the seventh signal path SL17.

A first branch path SL21 is formed so as to branch from an intermediate position of the first signal path SL11, and the first branch path SL21 is electrically connected to the management IC 66. Further, the second branch path SL22 is formed so as to branch from the middle position of the second signal path SL12, and the second branch path SL22 is electrically connected to the management IC 66. Further, a third branch path SL23 is formed so as to branch from an intermediate position of the third signal path SL13, and the third branch path SL23 is electrically connected to the management IC 66. Further, a fourth branch path SL24 is formed so as to branch from an intermediate position of the fourth signal path SL14, and the fourth branch path SL24 is electrically connected to the management IC 66. Further, a fifth branch path SL25 is formed so as to branch from an intermediate position of the fifth signal path SL15, and the fifth branch path SL25 is electrically connected to the management IC 66. Further, a sixth branch path SL26 is formed so as to branch from an intermediate position of the sixth signal path SL16, and the sixth branch path SL26 is electrically connected to the management IC 66. Further, a seventh branch path SL27 is formed so as to branch from an intermediate position of the seventh signal path SL17, and the seventh branch path SL27 is electrically connected to the management IC 66.

With the above configuration, the detection results of the respective ball detection sensors 42a to 48a are input to the management IC 66 without intervention of the processing by the main CPU 63. As a result, the main CPU 63 executes a process for causing the management CPU 112 to recognize the result of entering each of the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first operating opening 33, and the second operating opening 34. Since it is not necessary to do so, it is possible to reduce the processing load of the main CPU 63.

Further, branch points of the branch paths SL21 to SL27 from the signal paths SL11 to SL17 are present in the MPU 62. As a result, it is possible to make it difficult to access the branch point and each of the branch paths SL21 to SL27 from the outside, and it is possible to prevent an illegal act in which an abnormal entry result is input only to the management IC 66. ..

<Eleventh Embodiment>
In this embodiment, the configuration of the display device for displaying the management result of the game history is different from that of the first embodiment. The configuration different from that of the first embodiment will be described below. The description of the same configuration as that of the first embodiment is basically omitted.

FIG. 53 is a front view of main controller 60 in the present embodiment.

In the first embodiment, the main control device 60 is provided with the first notification display device 69a, the second notification display device 69b, and the third notification display device 69c, but in the present embodiment, the first notification display device 69a is provided. A display device 201, a second notification display device 202, a third notification display device 203, and a fourth notification display device 204 are provided. These first to fourth notification display devices 201 to 204 are provided side by side on the element mounting surface of the main control board 61.

Each of the first to fourth notification display devices 201 to 204 is a segment display in which seven display segments by LEDs are arranged, but the display device is not limited to this, and a single multicolor emission type single display device is used. It may be a light emitting body, a liquid crystal display device, or an organic EL display. The first to fourth notification display devices 201 to 204 are installed so that their display surfaces face the direction in which the element mounting surface of the main control board 61 faces, and by the facing wall portion 60b of the board box 60a. Is covered. In this case, since the substrate box 60a is formed transparent, the display surfaces of the first to fourth notification display devices 201 to 204 housed in the substrate box 60a are visually observed from the outside of the substrate box 60a. It becomes possible. Further, the main controller 60 is mounted on the back surface of the resin base 21 so that the facing wall portion 60b facing the element mounting surface of the main control board 61 in the board box 60a faces the back of the pachinko machine 10, so that the gaming machine. When the main body 12 is opened to the front of the pachinko machine 10 with respect to the outer frame 11 and the back surface of the resin base 21 is exposed to the front of the pachinko machine 10, the first to fourth notification display devices 201 through the facing wall portion 60b. It is possible to visually check the display surfaces of 204.

Alphabets such as "A", "E", "H", "L", and "O" are displayed on the display surface of the first notification display device 201. On the other hand, on the second notification display device 202, the third notification display device 203, and the fourth notification display device 204, numbers are displayed in the range of “0” to “9”. The management results of the game history are notified using the first to fourth notification display devices 201 to 204. In this case, the management results of the game history that is the notification target in the first notification display device 201 and the second notification display device 202 (the first to eighth parameters, the eleventh to eighteenth parameters in the first embodiment). Parameters, 21st to 26th parameters, 31st parameter, 41st to 42nd parameter) are displayed, and the third notification display device 203 and the fourth notification display device 204 become notification targets. A display corresponding to the content of the management result of the type of game history is performed.

Specifically, as the type of the management result of the game history, the first to eighth parameters, the first to eighteenth parameters, the twenty-first to twenty-sixth parameters, the thirty-first parameters, and the fourteenth to the forty-second parameters in the first embodiment. Exists. On the first notification display device 201, a display corresponding to the type of parameter group that is the notification target is performed. Specifically, when any of the first to eighth parameters is the notification target, “A” is displayed on the first notification display device 201, and any of the first to eighteenth parameters is displayed. If the notification target is the first notification display device 201, “E” is displayed, and if any of the 21st to 26th parameters is the notification target, the first notification display device. When “H” is displayed on 201 and any of the 31st parameters is the notification target, “L” is displayed on the first notification display device 201 and the 41st to 42nd parameters are notified. When it is a target, “O” is displayed on the first notification display device 201.

The second notification display device 202 displays the order corresponding to the type of the management result of the game history that is the notification target among the arrangement order of the management results of the game history in the parameter group that is the notification target. Explaining the parameter group of the first to eighth parameters as an example, when the first parameter is the notification target, “1” is displayed on the second notification display device 202, and the second parameter is When it is the notification target, “2” is displayed on the second notification display device 202, and when the third parameter is the notification target, “2” is displayed on the second notification display device 202. Is displayed, "4" is displayed on the second notification display device 202 when the fourth parameter is the notification target, and the second notification is displayed when the fifth parameter is the notification target. When "5" is displayed on the display device 202 and the sixth parameter is the notification target, "6" is displayed on the second notification display device 202 and the seventh parameter is the notification target. If it is, the second notification display device 202 displays “7”, and if the eighth parameter is the notification target, the second notification display device 202 displays “8”. Further, the parameter group of the 21st to 26th parameters will be described as an example. When the 21st parameter is the notification target, “1” is displayed on the second notification display device 202, and the 22nd parameter is displayed. When the parameter is the notification target, “2” is displayed on the second notification display device 202, and when the 23rd parameter is the notification target, the “2” is displayed on the second notification display device 202. "3" is displayed, "24" is displayed on the second notification display device 202 when the 24th parameter is the notification target, and "2" is displayed when the 25th parameter is the notification target. "5" is displayed on the notification display device 202, and "6" is displayed on the second notification display device 202 when the 26th parameter is the notification target.

For details of the display contents of the third notification display device 203 and the fourth notification display device 204, the numeral corresponding to the tens digit of the value obtained by multiplying the parameter to be notified by 100 is the third notification information. The number is displayed on the display device 203, and the number corresponding to the ones digit is displayed on the fourth notification display device 204.

In the 1st-4th notification display devices 201-204, the said 1st-8th parameter, the said 11th-18th parameter, the said 21st-26th parameter, the said 31st parameter, and the said 41st-42nd. The display corresponding to the parameter calculation result is sequentially switched according to a predetermined order, and after the calculation result of the 42nd parameter, which is the display object in the last order, is displayed, the first parameter that is the display object in the first order is displayed. The calculation result of is displayed. In this case, the period during which the calculation result of one parameter is continuously displayed is 2 seconds. On the other hand, the calculation cycle of the various parameters in the management CPU 112 is 51 seconds, and the number of various parameters is 25. Therefore, the various parameters calculated by the management-side CPU 112 are subject to notification in the first to fourth notification display devices 201 to 202 at least once.

In the first to fourth notification display devices 201 to 204, not only the notification of the management result of the game history but also the changeable state in which the setting state of the pachinko machine 10 can be changed as in the first embodiment. In, the value corresponding to the current set value is displayed. Specifically, in the changeable state, the first to third notification display devices 201 to 203 are turned off, whereas in the horizontally arranged first to fourth notification display devices 204, they are present at the right end. The value corresponding to the current set value is displayed on the fourth notification display device 204. That is, when “setting 1” is selected in the changeable state, “1” is displayed on the fourth notification display device 204, and when “setting 2” is selected in the changeable state When "2" is displayed on the fourth notification display device 204 and "Setting 3" is selected in the changeable state, "4" is displayed on the fourth notification display device 204 and can be changed. When "setting 4" is selected in the state, "4" is displayed on the fourth notification display device 204, and when "setting 5" is selected in the changeable state, the fourth notification is displayed. “5” is displayed on the display device 204, and when “setting 6” is selected in the changeable state, “6” is displayed on the fourth notification display device 204.

Next, an electrical configuration for performing various displays on the first to fourth notification display devices 201 to 204 based on the control of the MPU 62 will be described. FIG. 54 is a block diagram for explaining an electrical configuration for performing various displays on the first to fourth notification display devices 201 to 204 under the control of the MPU 62.

As described above, the MPU 62 and the first to fourth notification display devices 201 to 204 are provided on the main control board 61. Further, the main control board 61 is provided with a first display IC 205, a second display IC 206, a third display IC 207 and a fourth display IC 208.

The first display IC 205 is provided so as to correspond to the first notification display device 201, is electrically connected to the MPU 62 through the signal path SL31, and is electrically connected to the first notification display device 201 through the signal path SL32. It is connected. The first display IC 205 is provided with a storage buffer for storing the display data received from the MPU 62, and the display control of the first notification display device 201, that is, each display is performed according to the display data stored in the storage buffer. Control the light emission of the display segment. The first display IC 205 can store and hold the display data stored in the storage buffer when operating power is supplied, and the display content corresponding to the stored and held display data is displayed by the first notification display device. It is continuously displayed on 201. Then, the display data is changed by the MPU 62, so that the display on the first notification display device 201 is changed to the display content corresponding to the changed display data. In addition, after the supply of the operating power to the first display IC 205 is started and the display data is not set by the MPU 62, the display data is all “0” data. Indicates that the first notification display device 201 is in the non-display state, that is, in the extinguished state.

However, the present invention is not limited to this configuration, and even if the supply of operating power to the pachinko machine 10 is stopped by the backup power being supplied to the first display IC 205, the first display IC 205 displays The data may be stored and held. In this case, when the supply of the operating power to the pachinko machine 10 is started, the display performed on the first notification display device 201 immediately before the supply of the operating power of the pachinko machine 10 is stopped. It will be started by the first notification display device 201.

The second display IC 206 is provided corresponding to the second notification display device 202, is electrically connected to the MPU 62 through the signal path SL33, and is electrically connected to the second notification display device 202 through the signal path SL34. It is connected. The second display IC 206 is provided with a storage buffer for storing the display data received from the MPU 62, and the display control of the second notification display device 202, that is, each display, according to the display data stored in the storage buffer. Control the light emission of the display segment. The second display IC 206 can store and hold the display data stored in the storage buffer when operating power is supplied, and the display content corresponding to the stored and held display data is displayed on the second notification display device. It is continuously displayed on 202. Then, the display data is changed by the MPU 62, so that the display on the second notification display device 202 is changed to the display content corresponding to the changed display data. Further, in a situation after the supply of the operating power to the second display IC 206 is started and the display data is not set by the MPU 62, the display data is all “0” data. Indicates that the second notification display device 202 is in the non-display state, that is, in the extinguished state.

However, the configuration is not limited to this, and the second display IC 206 displays even if the supply of operating power to the pachinko machine 10 is stopped by the backup power being supplied to the second display IC 206. The data may be stored and held. In this case, when the supply of the operating power to the pachinko machine 10 is started, the display performed on the second notification display device 202 immediately before the supply of the operating power of the pachinko machine 10 is stopped. It will be started on the second notification display device 202.

The third display IC 207 is provided so as to correspond to the third notification display device 203, is electrically connected to the MPU 62 through the signal path SL35, and is electrically connected to the third notification display device 203 through the signal path SL36. It is connected. The third display IC 207 is provided with a storage buffer for storing the display data received from the MPU 62, and the display control of the third notification display device 203, that is, each display, according to the display data stored in the storage buffer. Control the light emission of the segment. The third display IC 207 can store and hold the display data stored in the storage buffer when operating power is supplied, and the display content corresponding to the stored and held display data is displayed by the third notification display device. The display is continued on 203. When the display data is changed by the MPU 62, the display of the third notification display device 203 is changed to the display content corresponding to the changed display data. Further, in a situation after the supply of the operating power to the third display IC 207 is started and the display data is not set by the MPU 62, the display data is all “0” data. Indicates that the third notification display device 203 is in the non-display state, that is, in the off state.

However, the present invention is not limited to this configuration, and the third display IC 207 displays even if the supply of operating power to the pachinko machine 10 is stopped by the backup power being supplied to the third display IC 207. The data may be stored and held. In this case, when the supply of the operating power to the pachinko machine 10 is started, the display performed on the third notification display device 203 immediately before the supply of the operating power of the pachinko machine 10 is stopped. It will be started on the third notification display device 203.

The fourth display IC 208 is provided so as to correspond to the fourth notification display device 204, is electrically connected to the MPU 62 through the signal path SL37, and is electrically connected to the fourth notification display device 204 through the signal path SL38. It is connected. The fourth display IC 208 is provided with a storage buffer for storing the display data received from the MPU 62, and the display control of the fourth notification display device 204, that is, each display is performed according to the display data stored in the storage buffer. Control the light emission of the display segment. The fourth display IC 208 can store and hold the display data stored in the storage buffer when operating power is supplied, and the display content corresponding to the stored and held display data is displayed by the fourth notification display device. The display is continued on 204. Then, the display data is changed by the MPU 62, so that the display of the fourth notification display device 204 is changed to the display content corresponding to the changed display data. Further, in the situation after the supply of the operating power to the fourth display IC 208 is started and the display data is not set by the MPU 62, the display data is all “0” data. Indicates that the fourth notification display device 204 is in the non-display state, that is, in the extinguished state.

However, the present invention is not limited to this configuration, and even if the supply of operating power to the pachinko machine 10 is stopped by the backup power being supplied to the fourth display IC 208, it is displayed on the fourth display IC 208. The data may be stored and held. In this case, when the supply of the operating power to the pachinko machine 10 is started, the display performed on the fourth notification display device 204 immediately before the supply of the operating power of the pachinko machine 10 is stopped is concerned. It will be started by the fourth notification display device 204.

Output of display data to the first to fourth display ICs 205 to 208 is performed by the MPU 62, and output setting of the display data is performed by each of the main CPU 63 and the management CPU 112. That is, the main CPU 63 executes the display control of the first to fourth notification display devices 201 to 204, and the management CPU 112 executes the display control of the first to fourth notification display devices 201 to 204. In this case, the period in which the output setting of the display data is performed is adjusted so that the output setting of the display data is not performed at the same time in the main CPU 63 and the management CPU 112. Specifically, the setting state of the pachinko machine 10 can be changed after the supply of operating power to the MPU 62 is started. In the changeable state, the output setting of the display data by the main CPU 63 is performed. On the other hand, display data output setting by the management CPU 112 is not performed. On the other hand, in the state where the setting value cannot be changed, the display data output setting is performed by the management CPU 112, whereas the display data output setting by the main CPU 63 is not performed.

If the output setting of the display data by the main CPU 63 and the output setting of the display data by the management CPU 112 are performed at the time of synchronization, the output setting of the display data by the main CPU 63 has priority. However, the present invention is not limited to this, and the display data output setting by the management CPU 112 may be prioritized.

Next, the display processing in this embodiment executed by the management-side CPU 112 will be described with reference to the flowchart of FIG.

First, the value of the update timing counter of the management RAM 114 is decremented by 1 (step S3001). The update timing counter is a counter for the management-side CPU 112 to specify that it is the time to update the display content of the management result of the game history on the first to fourth notification display devices 201 to 204. After that, by determining whether or not the value of the update timing counter after subtracting 1 is “0”, whether or not it is time to update the display contents of the first to fourth notification display devices 201 to 204 Is determined (step S3002).

When an affirmative determination is made in step S3002, the value of the display target counter of the management side RAM 114 is incremented by 1 (step S3003). When the value of the display target counter after adding 1 exceeds the maximum value of "24" (step S3004: YES), the value of the display target counter is cleared to "0" (step S3005). The display target counter is a counter for the management-side CPU 112 to specify the type of parameter to be displayed on the first to fourth notification display devices 201 to 204. Of the first to eighth parameters, the first to eighteenth parameters, the twenty-first to twenty-sixth parameters, the thirty-first parameters and the fourteenth to forty-second parameters, and the display target counter of "0" to "24". There is a one-to-one correspondence with the possible values. For example, when the value of the display target counter is “0”, the first parameter, which is the first display target, becomes the display target of the first to fourth notification display devices 201 to 204, and the value of the display target counter is “24”. In this case, the 42nd parameter which is the last display target is the display target of the first to fourth notification display devices 201 to 204.

When a negative determination is made in step S3004, or when the processing of step S3005 is executed, display data corresponding to the type of parameter corresponding to the value of the display target counter is read from the management side ROM 113 (step S3006). Then, the display data setting process corresponding to the first notification display device 201 is executed (step S3007), and the display data setting process corresponding to the second notification display device 202 is executed (step S3008). For example, if the value of the display target counter is “0” and the first parameter is the display target, the display data for displaying “A” on the first notification display device 201 is displayed on the first display IC 205. In addition to the output, the display data for displaying “1” on the second notification display device 202 is output to the second display IC 206. Further, for example, if the value of the display target counter is “24” and the 42nd parameter is the display target, the display data for displaying “O” on the first notification display device 201 is first displayed. The display data for displaying “2” on the second notification display device 202 is output to the second display IC 206 while being output to the IC 205.

After that, the parameter corresponding to the value of the display target counter is read from the calculation result memory 131, and the display data corresponding to the tens place and the display data corresponding to the ones place of the result obtained by multiplying the read parameter by 100 are displayed. It is read from the management-side ROM 113 (step S3009). Then, the display control of the third notification display device 203 is performed so that the number corresponding to the tens digit of the result is displayed (step S3010), and the fourth number is displayed so that the number corresponding to the ones place is displayed. The display of the notification display device 204 is controlled (step S3011). For example, when the result multiplied by 100 is “53”, the display data for displaying “5” on the third notification display device 203 is output to the third display IC 207 and the fourth notification display device 204 is displayed. The display data for displaying “3” is output to the fourth display IC 208.

After that, a value corresponding to 2 seconds is set as a value corresponding to the next update timing in the update timing counter of the management side RAM 114 (step S3012).

By executing the display process as described above, the game history management result is displayed on the first to fourth notification display devices 201 to 204. The management result of the game history is displayed regardless of whether the game is continued or not, and the main body of the gaming machine 12 is opened with respect to the outer frame 11 so that the main controller 60 is operated from the front of the pachinko machine 10. It is performed regardless of whether it is visible. In this way, the display control of the first to fourth notification display devices 201 to 204 is executed regardless of the game situation or the state of the pachinko machine 10, so that the first to fourth notification display device 201 is executed. It is possible to simplify the processing configuration for controlling the display of ~ 204.

The display of the game history management result on the first to fourth notification display devices 201 to 204 is started after the supply of the operating power to the management CPU 112 is started and after the identification end command is received from the main CPU 63. To be done. In this case, like the information stored in the history memory 117, the information stored in the calculation result memory 131 is stored and retained even when the supply of operating power to the pachinko machine 10 is stopped. Therefore, when the supply of the operating power to the management-side CPU 112 is started, the management result of the game history calculated before the supply of the operating power to the management-side CPU 112 is stopped is displayed.

The first to fourth display ICs 205 to 208 store and hold the display data output from the MPU 62 while operating power is being supplied, and the corresponding first to fourth notification display devices 201 to 204 according to the display data. Display control. Therefore, after the display of the management result of the game history is started, the first to fourth notification display devices 201 to 204 are not in the off state (that is, the non-display state), and the lighting state corresponding to some display ( That is, the display state).

Next, the setting value update processing in this embodiment executed by the main CPU 63 will be described with reference to the flowchart in FIG.

First, the extinguishing process of the first to third notification display devices 201 to 203 is executed (step S3101). Specifically, the display data that is all “0” is output to the first to third display ICs 205 to 207. As a result, all the display segments of the first to third notification display devices 201 to 203 are turned off, and the first to third notification display devices 201 to 203 are turned off. Immediately after the supply of the operating power to the pachinko machine 10 is started, the display segments of the first to fourth notification display devices 201 to 204 are all in the off state and the first to fourth notification display device 201. ˜204 are non-display states. Therefore, step S3101 is a process of maintaining the first to third notification display devices 201 to 203 in the non-display state, and if any of the first to third notification display devices 201 to 203 is caused by some influence. If it is in the display state, it is a process of making it in the non-display state.

After that, "1" is set to the set value counter of the main RAM 65 (step S3102). The set value counter is a counter for the main CPU 63 to specify which set value the set state of the pachinko machine 10 is. By setting "1" in the set value counter, when the set value updating process is executed, the set value becomes "set 1" regardless of the set value up to that point.

Then, the display start processing of the set value on the fourth notification display device 204 is executed (step S3103). In the setting value display start processing, display data for displaying “1” is output to the fourth display IC 208. As a result, the number “1” corresponding to “Setting 1” is displayed on the fourth notification display device 204.

Then, it is determined whether the update button 68b has been pressed once (step S3105) on condition that the setting key insertion portion 68a has not been operated OFF (step S3104: NO). Specifically, it is determined whether or not the signal from the sensor that detects the pressing operation of the update button 68b has switched from the LOW level to the HI level. When a negative determination is made in step S3105, the process returns to step S3104 and it is determined whether or not the setting key insertion portion 68a has been turned off.

When the update button 68b is pressed once (step S3105: YES), the value of the set value counter of the main RAM 65 is incremented by 1 (step S3106). When the value of the set value counter after adding 1 exceeds "6" (step S3107: YES), "1" is set in the set value counter (step S3108). As a result, each time the update button 68b is pressed once, it is updated to the set value one step higher, and when the update button 68b is pressed once in the situation of "setting 6", it is set to "setting 1". Will return.

If a negative determination is made in step S3107, or if the processing of step S3108 is executed, display updating processing of the set value in the fourth notification display device 204 is executed (step S3109). In the display update process of the set value, the display data for displaying the number corresponding to the value of the set value counter of the main RAM 65 is output to the fourth display IC 208. As a result, the number corresponding to the current set value is displayed on the fourth notification display device 204. By checking the fourth notification display device 204, the manager of the game hall can grasp the setting state of the pachinko machine 10 after pressing the update button 68b.

After executing the process of step S3109, the process returns to step S3104, and it is determined whether or not the setting key insertion unit 68a has been turned off. When the OFF operation has not been performed (step S3104: NO), the processes of step S3105 and thereafter are executed again. If the OFF operation has been performed (step S3104: YES), display start processing of the management result in the first to fourth notification display devices 201 to 204 is executed (step S3110).

In the display start process, the display start command of the management result is transmitted from the main CPU 63 to the management CPU 112. Upon receiving the management result display start command, the management-side CPU 112 executes a process for displaying the first parameter of the various parameters stored in the calculation result memory 131. The processing contents in this case are the same as steps S3006 to S3012 in the display process (FIG. 55). Accordingly, the display corresponding to the first parameter calculated immediately before the operation power of the pachinko machine 10 is stopped last time is displayed on the first to fourth notification display devices 201 to 204.

Next, the display modes of the first to fourth notification display devices 201 to 204 when the game history management result is displayed and when the setting state of the pachinko machine 10 is updated will be described. FIG. 57(a) is an explanatory diagram for explaining display modes of the first to fourth notification display devices 201-204 when the game history management result is displayed, and FIG. 57(b) is a pachinko machine. It is explanatory drawing for demonstrating the display mode of the 1st-4th notification display apparatuses 201-204 in case the setting state of 10 is changed.

When the management result of the game history is displayed, at least one display segment is in a light emitting state in each of the first to fourth notification display devices 201 to 204 as shown in FIG. 57(a). That is, each of the first to fourth notification display devices 201 to 204 is in a display state. This is the same regardless of which of the first to eighth parameters, the eleventh to eighteenth parameters, the twenty-first to twenty-sixth parameters, the thirty-first parameter, and the fourteenth to the forty-second parameter are to be notified. .. Thereby, the manager of the game hall visually confirms that all of the first to fourth notification display devices 201 to 204 are in the display state. It is possible to understand that the management result of the game history is displayed.

On the other hand, when the setting state of the pachinko machine 10 is changed, all the display segments are turned off in each of the first to third notification display devices 201 to 203 as shown in FIG. 57(b). That is, each of the first to third notification display devices 201 to 203 is in the non-display state. Further, any one of "1" to "6" is displayed on the fourth notification display device 204. As described above, by displaying any one of “1” to “6” on the fourth notification display device 204 and each of the first to third notification display devices 201 to 203 being in the non-display state, It becomes possible for the manager of the game hall to understand that the display corresponding to the set value is being performed on the first to fourth notification display devices 201 to 204, and to clearly understand the current set value. It becomes possible.

Next, the manner in which the first to fourth notification display devices 201 to 204 are in the display state will be described with reference to the time charts of FIGS. 58(a) to 58(h). FIG. 58A shows a changeable state period in which the setting state of the pachinko machine 10 can be changed, and FIG. 58B shows a setting display update on the first to fourth notification display devices 201 to 204. 58C shows the timing, FIG. 58C shows a period in which the game history management result is displayed on the first to fourth notification display devices 201 to 204, and FIG. 58D is the first to fourth notification display device. The display update timing corresponding to the management result of the game history in 201-204 is shown, FIG.58(e) shows the period when the 1st notification display apparatus 201 is in a display state, and FIG.58(f) shows it. 2 shows the period during which the notification display device 202 is in the display state, FIG. 58(g) shows the period during which the third notification display device 203 is in the display state, and FIG. 58(h) shows the fourth notification. The period during which the display device 204 is in the display state is shown.

By changing the setting state of the pachinko machine 10 at the timing of t1 as shown in FIG. 58(a) by starting to supply the operating power to the pachinko machine 10 with the setting key insertion section 68a being turned on. Can be changed. At the timing of t1, the setting display is updated as shown in FIG. 58B, the fourth notification display device 204 is in the display state as shown in FIG. 58H, and the display state is continued. In this case, since “setting 1” has been selected, “1” is displayed on the fourth notification display device 204. On the other hand, at the timing of t1, as shown in FIGS. 58(e) to 58(g), the first to third notification display devices 201 to 203 are in a non-display state, that is, all display segments are turned off. Maintained.

After that, the operation of changing the set value by the operation of the update button 68b is performed at each of the timing of t2, the timing of t3, the timing of t4, and the timing of t5, and as shown in FIG. Is the update timing of the set value display. In this case, as shown in FIG. 58(h), in the fourth notification display device 204, the display content is switched to the number corresponding to the changed set value at each timing, but the display content is switched. The fourth notification display device 204 is maintained in the display state including the respective timings at which On the other hand, as shown in FIGS. 58(e) to 58(g), the display devices 201 to 203 for the first to third notifications are in the non-display state, that is, for all the display, at each of the update timings of these set value displays. The segment remains off.

Thereafter, the setting key insertion portion 68a is turned off at the timing of t6, and the changeable state is ended as shown in FIG. 58(a). In this case, the display period of the game history management result is started at the timing of t6 as shown in FIG. 58(c). Specifically, the display of the first parameter stored in the calculation result memory 131 is started. Therefore, at the timing of t6, as shown in FIGS. 58(e) to 58(g), the first to third notification display devices 201 to 203 are switched from the non-display state to the display state and the fourth notification display is performed. Although the display content of the device 204 is changed, the display state is maintained.

Thereafter, at each of the timing of t7, the timing of t8, the timing of t9, the timing of t10, the timing of t11, and the timing of t12, as shown in FIG. 58(d), the display timing of the management result of the game history is updated. In this case, as shown in FIGS. 58(e) to 58(h), the display contents corresponding to the management result of the updated game history at each of the timings in the first to fourth notification display devices 201 to 204. Although it is switched, all of the first to fourth notification display devices 201 to 204 are maintained in the display state including the timings at which the display contents are switched.

According to this embodiment described in detail above, the following excellent effects are exhibited.

In the configuration in which the management result of the game history is displayed on the first to fourth notification display devices 201 to 204, the setting state of the pachinko machine 10 can be changed. In the changeable state, the corresponding display is displayed. This is performed by the first to fourth notification display devices 201 to 204. As a result, it becomes possible to use the first to fourth notification display devices 201 to 204 not only for displaying the management result of the game history but also as a display device for performing the corresponding display in the changeable state. ..

Corresponding to the period in which the game history management result is displayed on the first to fourth notification display devices 201 to 204 and the set value changeable state on the first to fourth notification display devices 201 to 204. It is distinguished from the period in which the display is made. Accordingly, by grasping the situation in which the display is performed on the first to fourth notification display devices 201 to 204, which display is performed on the first to fourth notification display devices 201 to 204. It becomes possible to specify whether or not there is.

When the display corresponding to the changeable state of the set value is performed, the first to fourth notification display devices 201 to 204 have different display modes from the display mode when the game history management result is displayed. Display controlled. Accordingly, by grasping the display modes of the first to fourth notification display devices 201 to 204, it is possible to identify which display is being performed on the first to fourth notification display devices 201 to 204. It becomes possible.

A plurality of notification display devices 201 to 204 are provided. As a result, a wide variety of displays can be performed as the display corresponding to the management result of the game history. In addition, due to the presence of the plurality of display devices 201 to 204 for notification, the display mode is large depending on whether the management result of the game history is displayed or the display corresponding to the changeable state of the set value is performed. It is possible to make a difference.

When the display corresponding to the changeable state of the set value is performed, the first to third notification display devices 201 to 203 that are not in the non-display state when displaying the management result of the game history are in the non-display state. Thereby, the display of the management result of the game history and the display corresponding to the changeable state of the set value are performed only by confirming whether the first to third notification display devices 201 to 203 are in the non-display state. It is possible to clearly specify which one of them is performed on the first to fourth notification display devices 201 to 204.

When the display corresponding to the changeable state of the set value is performed, the fourth notification display device 204 is in the display state, and the display content is the fourth notification display device 204 when the management result of the game history is displayed. These are the display contents that can be displayed in. By thus allowing the display contents on the fourth notification display device 204 to be duplicated, the case where the management result of the game history is displayed and the case where the display corresponding to the changeable state of the set value is performed, respectively. It is possible not to give any restriction to the display contents of. Even if the display contents on the fourth notification display device 204 are duplicated as described above, if the display corresponding to the changeable state of the set value is performed, the first to third notification display devices are displayed. Since 201 to 203 are in the non-display state, it is possible to specify which display is being performed on the first to fourth notification display devices 201 to 204.

When the management result of the game history is displayed, each of the first to fourth notification display devices 201 to 204 is in a display state. Thereby, the display modes of the first to fourth notification display devices 201 to 204 are clearly different between when the management result of the game history is displayed and when the display corresponding to the changeable state of the set value is performed. It becomes possible.

When the management result of the game history is displayed, the first to fourth notification display devices 201 to 204 are not maintained in the non-display state even when the type of the management result of the game history to be displayed is changed. .. This makes it possible to specify the game history management result regardless of the timing at which the first to fourth notification display devices 201 to 204 are confirmed in the situation where the game history management result is displayed. In addition, regardless of the timing at which the first to fourth notification display devices 201 to 204 are confirmed, the game history management result is displayed and the set value can be changed in the first to fourth notification display devices 201 to 204. It becomes possible to specify which of the corresponding displays is being performed.

When the display corresponding to the changeable state of the set value is performed, only one of the fourth notification display devices 204 is in the display state. As a result, it becomes easy to understand whether or not the display corresponding to the changeable state of the set value is displayed.

In the configuration in which the first to fourth notification display devices 201 to 204 are arranged in the horizontal direction, only the fourth notification display device 204 arranged at the right end is used to display a display corresponding to the changeable state of the set value. Done. As a result, it becomes easy to understand whether or not the display corresponding to the changeable state of the set value is displayed.

When the management result of the game history is displayed, a display corresponding to the type of the management result of the game history to be displayed is performed using the first notification display device 201 and the second notification display device 202. Using the third notification display device 203 and the fourth notification display device 204, a display corresponding to the content of the management result of the game history is performed. This makes it easy to understand the management result of the game history. In this case, both the first notification display device 201 and the second notification display device 202 in which the type of the game history management result is displayed are in the non-display state in the set value changeable state. As a result, the non-display state of the first and second notification display devices 201 and 202 for displaying the type corresponds to the changeable state of the set value, which corresponds to the changeable state of the set value. It becomes easy to understand that the display is being performed.

Further, when the display corresponding to the changeable state of the set value is performed, not only the first notification display device 201 and the second notification display device 202 that display the type of the management result of the game history, but also the game The third annunciation display device 203 in which the content of the history management result is displayed is also in the non-display state. This makes it easy to understand that the display corresponding to the changeable state of the set value is being performed.

Display data is output from the MPU 62 to the first to fourth display ICs 205 to 208, and the first to fourth display ICs 205 to 208 perform predetermined display on the first to fourth notification display devices 201 to 204 according to the display data. In the configuration, the display data is stored and held by the first to fourth display ICs 205 to 208. Thereby, even when the execution of the process for advancing the game in the main CPU 63 is stopped due to the occurrence of the electric wave detection abnormality or the vibration detection abnormality (in the case of making a positive determination in step S306), It is possible to maintain the display of the management result of the game history on the first to fourth notification display devices 201 to 204.

In addition, in the changeable state in which the setting state of the pachinko machine 10 can be changed among the first to fourth notification display devices 201 to 204, the targets to be in the non-display state (all extinguished state) are: The display units 201 to 203 are not limited to the third display units 201 to 203, and the first and second display units 201 and 202 may be used. In this case, a predetermined display (for example, a display of “5”) different from the content of the current setting value is displayed on the third notification display device 203, and the current setting value is displayed on the fourth notification display device 204. May be displayed, and a predetermined display (for example, display of "5") different from the content of the current set value is displayed on the fourth notification display device 204 and the third notification is displayed. The display device 203 may display a number corresponding to the current set value. In addition, the first notification display device 201 and the third notification display device 203 are in a non-display state (all extinguished state), and the second notification display device 202 and the fourth notification display device 204 are in a display state. Alternatively, the first notification display device 201 and the fourth notification display device 204 are in the non-display state (all lights off state), and the second notification display device 202 and the third notification display device 203 are in the display state. The second notification display device 202 and the third notification display device 203 are in a non-display state (all lights off state), and the first notification display device 201 and the fourth notification display device 204 are displayed. The second notification display device 202 and the fourth notification display device 204 are in a non-display state (all extinguished state), and the first notification display device 201 and the third notification display device 203 May be in a display state.

Further, in the changeable state in which the setting state of the pachinko machine 10 can be changed, only the first notification display device 201 may be in the non-display state (all off state). Only the display device 202 may be in the non-display state (all off state), only the third notification display device 203 may be in the non-display state (all off state), and the fourth notification display device. Only 204 may be in a non-display state (all extinguished state).

Further, in the changeable state in which the setting state of the pachinko machine 10 can be changed, only the first notification display device 201 may be displayed, and only the second notification display device 202 is displayed. The third notification display device 203 alone may be in the display state.

<Twelfth Embodiment>
In the present embodiment, the display contents of the first notification display device 201 and the second notification display device 202 in the set value changeable state are different from those of the eleventh embodiment. The configuration different from the eleventh embodiment will be described below. The description of the same configuration as the eleventh embodiment is basically omitted.

59A is an explanatory diagram for explaining the configuration of the first notification display device 201, and FIG. 59B is an explanatory diagram for describing the configuration of the second notification display device 202.

As shown in FIG. 59(a), the first notification display device 201 includes seven first to seventh display segments 201a to 201g. Each of the first to seventh display segments 201a to 201g is formed in a rod shape and has a light emitting body such as an LED inside. These seven first to seventh display segments 201a to 201g are arranged so that the first notification display device 201 is a so-called 7-segment display.

As shown in FIG. 59B, the second notification display device 202 includes seven first to seventh display segments 202a to 202g. Each of the first to seventh display segments 202a to 202g is formed in a rod shape and has a light emitting body such as an LED inside. These seven first to seventh display segments 202a to 202g are arranged such that the second notification display device 202 is a so-called seven-segment display.

FIG. 60 shows a case where the game history management result is displayed on the first to fourth notification display devices 201 to 204 and a case where the setting state of the pachinko machine 10 is changeable. FIG. 3 is an explanatory diagram for explaining display contents of a first notification display device 201 and a second notification display device 202 in FIG.

The display contents of the first notification display device 201 and the second notification display device 202 when displaying the game history management result are the same as in the eleventh embodiment. Therefore, any one of “A”, “E”, “H”, “L”, and “O” is displayed on the first notification display device 201, and “1” to “8” on the second notification display device 202. Is displayed.

In this case, each of the first to seventh display segments 201a to 201g of the first notification display device 201 is "A", "E", "H", "L" in the first notification display device 201. At least one type of display of “O” is a light emission target. In other words, the display segments 201a to 201g that are not the light emission targets are displayed regardless of which of "A", "E", "H", "L", and "O" is displayed on the first notification display device 201. It doesn't exist.

Similarly for the second notification display device 202, each of the first to seventh display segments 202a to 202g of the second notification display device 202 is "1" to "8" in the second notification display device 202. In at least one type of display, the light emission target is displayed. In other words, there is no display segment 202a to 202g that is not the light emission target regardless of which of "1" to "8" is displayed on the second notification display device 202.

In the changeable state in which the setting state of the pachinko machine 10 can be changed, the second display segment 201b and the fifth display segment 201e are in the light emitting state in the first notification display device 201. As described above, the second display segment 201b and the fifth display segment 201e can be in a light emitting state when the game history management result is displayed on the first notification display device 201. In addition, the second display segment 201b and the fifth display segment 201e are in the light emitting state in any case where the game history management result is displayed on the first notification display device 201. On the other hand, among the first to seventh display segments 201a to 201g, only the second display segment 201b and the fifth display segment 201e are in the light emitting state. It does not exist when displaying results. Thereby, in the state where the set value can be changed, a display that is not displayed when displaying the game history management result while using the display segments 201b and 201e that can be in a light emitting state when displaying the game history management result The mode can be displayed on the first notification display device 201. Therefore, the display corresponding to the changeable state of the set value can be displayed on the first notification display device 201 while also using the display segments 201a to 201g used when displaying the management result of the game history. It will be possible.

In the state in which the set value can be changed, the third display segment 202c in the second notification display device 202 is in the light emitting state. As described above, the third display segment 202c can be in the light emitting state when the game history management result is displayed on the second notification display device 202. On the other hand, among the first to seventh display segments 202a to 202g, only the third display segment 202c is in a light emitting state, and the display content of the second notification display device 202 is present when the game history management result is displayed. I haven't. Thereby, in the changeable state of the set value, a display mode is displayed which is not displayed when displaying the management result of the game history while using the display segment 202c which can be in the light emitting state when displaying the management result of the game history. It becomes possible to display it on the second notification display device 202. Therefore, it is possible to cause the second notification display device 202 to perform a display corresponding to the changeable state of the set value while also using the display segments 202a to 202g used when displaying the management result of the game history. It will be possible.

Next, the setting value update processing in this embodiment executed by the main CPU 63 will be described with reference to the flowchart of FIG.

First, the start processing of displaying the set values on the first to second notification display devices 201 and 202 is executed (step S3201). Specifically, regarding the first notification display device 201, the second display segment 201b and the fifth display segment 201e are in the light emitting state, and the other display segments 201a, 201c, 201d, 201f, 201g are in the off state. The following display data is output to the first display IC 205. Further, regarding the second notification display device 202, display data is output to the second display IC 206 in which the third display segment 202c is in the light emitting state and the other display segments 202a, 202b, 202d to 202g are in the off state. As a result, the display for notifying that the pachinko machine 10 is in the changeable state in which the setting state can be changed is started on the first notification display device 201 and the second notification display device 202.

Then, the extinguishing process of the third notification display device 203 is executed (step S3202). Specifically, the display data that is all “0” is output to the third display IC 207. As a result, all the display segments of the third notification display device 203 are turned off, and the third notification display device 203 is in the non-display state.

After that, "1" is set to the set value counter of the main RAM 65 (step S3203). The set value counter is a counter for the main CPU 63 to specify which set value the set state of the pachinko machine 10 is. By setting "1" in the set value counter, when the set value updating process is executed, the set value becomes "set 1" regardless of the set value up to that point.

After that, the display start processing of the set value on the fourth notification display device 204 is executed (step S3204). In the setting value display start processing, display data for displaying “1” is output to the fourth display IC 208. As a result, the number “1” corresponding to “Setting 1” is displayed on the fourth notification display device 204.

After that, on condition that the setting key insertion portion 68a has not been turned off (step S3205: NO), it is determined whether or not the update button 68b has been pressed once (step S3206). Specifically, it is determined whether or not the signal from the sensor that detects the pressing operation of the update button 68b has switched from the LOW level to the HI level. When a negative determination is made in step S3206, the process returns to step S3205 and it is determined whether or not the setting key insertion portion 68a has been turned off.

When the update button 68b is pressed once (step S3206: YES), the value of the set value counter of the main RAM 65 is incremented by 1 (step S3207). When the value of the set value counter after adding 1 exceeds "6" (step S3208: YES), "1" is set in the set value counter (step S3209). As a result, each time the update button 68b is pressed once, it is updated to the set value one step higher, and when the update button 68b is pressed once in the situation of "setting 6", it is set to "setting 1". Will return.

If a negative determination is made in step S3208, or if the process of step S3209 is executed, the display update process of the set value in the fourth notification display device 204 is executed (step S3210). In the display update process of the set value, the display data for displaying the number corresponding to the value of the set value counter of the main RAM 65 is output to the fourth display IC 208. As a result, the number corresponding to the current set value is displayed on the fourth notification display device 204. By checking the fourth notification display device 204, the manager of the game hall can grasp the setting state of the pachinko machine 10 after pressing the update button 68b.

After executing the process of step S3210, the process returns to step S3205, and it is determined whether or not the setting key insertion unit 68a has been turned off. When the OFF operation has not been performed (step S3205: NO), the processes of step S3206 and subsequent steps are executed again. If the OFF operation has been performed (step S3205: YES), display start processing of the management result in the first to fourth notification display devices 201 to 204 is executed (step S3211).

In the display start process, the display start command of the management result is transmitted from the main CPU 63 to the management CPU 112. Upon receiving the management result display start command, the management-side CPU 112 executes a process for displaying the first parameter of the various parameters stored in the calculation result memory 131. The processing contents in this case are the same as steps S3006 to S3012 in the display process (FIG. 55). Accordingly, the display corresponding to the first parameter calculated immediately before the operation power of the pachinko machine 10 is stopped last time is displayed on the first to fourth notification display devices 201 to 204.

According to this embodiment described in detail above, the following excellent effects are exhibited.

The set value can be changed by setting the display segments 201a to 201g and 202a to 202g of the first and second notification display devices 201 and 202 that can be in the light emitting state when the game history management result is displayed to the light emitting state. A display corresponding to the status is made. As a result, in diversifying the display of the game history management result, it is possible to prevent the content of the display corresponding to the game history management result from being restricted as much as possible. On the other hand, for each of the first notification display device 201 and the second notification display device 202, the display segments 201a to 201g, 202a to become the light emitting state when the display corresponding to the changeable state of the set value is performed. The combination of 202g is a combination that does not exist when the management result of the game history is displayed. As a result, by grasping the combination of the display segments 201a to 201g and 202a to 202g that are in the light emitting state for each of the first notification display device 201 and the second notification display device 202, display of the game history management result It is possible to understand which of the displays corresponding to the changeable state of the set value and the set value is displayed.

For each of the first notification display device 201 and the second notification display device 202, there are display segments 201a to 201g and 202a to 202g that are not in a light emitting state even if the game history management results are displayed in all patterns. I haven't. As a result, in diversifying the display corresponding to the management result of the game history, it is possible to prevent the display contents of the management result of the game history from being restricted as much as possible.

When the display corresponding to the changeable state of the set value is performed, the third notification display device 203 that is not in the non-display state when displaying the management result of the game history is in the non-display state. As a result, not only the display contents of the first notification display device 201 and the second notification display device 202, but also whether or not the third notification display device 203 is in the non-display state is confirmed. It is possible to clearly specify which of the display of the management result and the display corresponding to the changeable state of the set value is performed on the first to fourth notification display devices 201 to 204.

Note that it is possible to change the setting state of the pachinko machine 10 in the first and second notification display devices 201 and 202, and is limited to the configuration in which only one type of display content corresponding to the changeable state is set. Instead, a plurality of types may be set. In this case, the display order of the plurality of types of display content may be predetermined, and the display content to be displayed may be changed according to the display order each time the changeable state is newly executed. Even when there are a plurality of types of display contents corresponding to the changeable state of set values, the display contents are in the light emitting state when the game history management result is displayed. .About.201g, 202a to 202g are displayed, and the display contents are not displayed when the management result of the game history is displayed.

In addition, in one of the case of displaying the management result of the game history and the case of displaying corresponding to the changeable state in which the setting state of the pachinko machine 10 can be changed, the first and second notification display devices It is also possible to adopt a configuration in which blinking display is performed in 201 and 202, and display that keeps lighting is performed in the other. In this case, since it is possible for the manager of the game hall to specify which of the display of the management result of the game history and the display corresponding to the changeable state, it can be changed depending on whether the display is blinking or lit. The combination of the display segments 201a to 201g and 202a to 202g which are in the light emitting state in the display corresponding to the possible state may be the combination used when displaying the management result of the game history, and the management of the game history. It may be a combination that is not used when displaying the result. The lighting period and the extinguishing period in the blinking display may be the same in the first notification display device 201 and the second notification display device 202, or may be completely deviated. The configuration may be such that only part of them overlap.

<Thirteenth Embodiment>
In the present embodiment, when an abnormal state occurs in the pachinko machine 10, a display corresponding to the abnormal state is performed using the first to fourth notification display devices 201 to 204, which is different from the eleventh embodiment. There is. The configuration different from the eleventh embodiment will be described below. The description of the same configuration as the eleventh embodiment is basically omitted.

FIG. 62 is an explanatory diagram for explaining the configuration of the abnormality display area 211 provided in the main RAM 65.

The abnormality display area 211 is an area for storing information on an abnormal state to be displayed on the first to fourth notification display devices 201 to 204. The abnormality display area 211 is provided with a plurality of unit areas 211a to 211d. Specifically, the first unit area 211a, the second unit area 211b, the third unit area 211c, and the fourth unit area 211d are provided. It is possible to store information on the abnormal state of the pachinko machine 10 one by one in each of the first to fourth unit areas 211a to 211d. That is, in the abnormality display area 211, a maximum of four pieces of information on the abnormal state of the pachinko machine 10 can be stored and held.

Here, in the present embodiment, the main CPU 63 specifies all the information about the abnormal state that occurs in the pachinko machine 10. For example, when an abnormality relating to the payout of gaming balls (for example, the lower tray 56a is full, the ball in the tank 75 is absent, a payout abnormality by the payout device 76) occurs, a command corresponding to the generated abnormality is issued to the payout CPU 92. From the main CPU 63. Further, the pachinko machine 10 is provided with a radio wave detection sensor and a vibration detection sensor (not shown), and when an illegal radio wave is detected by the radio wave detection sensor, an abnormal signal corresponding thereto is transmitted to the main CPU 63 to cause an abnormal condition. When the vibration detection sensor detects vibration, an abnormal signal corresponding to the detected vibration is transmitted to the main CPU 63. Further, the occurrence of disconnection abnormality of these ball detection sensors 42a to 49a is specified based on the fact that normal signals are not transmitted from the ball detection sensors 42a to 49a.

The type of abnormal state specified by the main CPU 63 is larger than the maximum number of abnormal state information that can be stored in the abnormal display area 211. Then, when a large number of abnormal states occur at the same time, it is expected that new abnormal information will occur although the maximum number of abnormal state information is already stored in the abnormal display area 211. On the other hand, for the information on the abnormal state, the storage priority is set in the setting stage of the pachinko machine 10, and in the situation where the maximum number of information on the abnormal state has already been stored in the abnormality display area 211, When an abnormal state occurs in the abnormal state, information of the abnormal state having a high storage priority is left in the abnormal display area 211. As a result, it becomes possible to give priority to the notification of an abnormal state having a high storage priority.

Next, the abnormality setting process executed by the main CPU 63 will be described with reference to the flowchart of FIG. The abnormality setting process is executed as the first process of the timer interrupt process (FIG. 11).

First, it is determined whether or not an abnormality display target has occurred (step S3301). The types of the abnormality display target include full filling of the lower plate 56a, no ball of the tank 75, abnormality of the dispensing by the dispensing device 76, abnormality of radio wave detection, abnormality of vibration detection, disconnection abnormality of each of the ball detection sensors 42a to 49a. The number of types of abnormality display targets is larger than the number of the first to fourth unit areas 211a to 211d provided in the abnormality display area 211.

If an affirmative decision is made in step S3301, whether or not the abnormal state information corresponding to the abnormal display target that has occurred this time is already stored in any of the first to fourth unit areas 211a to 211d of the abnormal display area 211. Is determined (step S3302). If already stored, the abnormal state information corresponding to the abnormal display target that has occurred this time is not stored in the abnormal display area 211. This makes it possible to prevent the same type of abnormal state information from being redundantly stored in the abnormal display area 211.

When a negative determination is made in step S3302, it is determined whether or not the value of the abnormality target counter provided in the main RAM 65 is the maximum value (specifically "4") (step S3303). The abnormality target counter is a counter for the main CPU 63 to specify the number of areas in the abnormality display area 211 in which the information on the abnormal state is stored among the first to fourth unit areas 211a to 211d.

When the value of the abnormality target counter is the maximum value (step S3303: YES), priority comparison processing is executed (step S3304). In the priority comparison process, first, the abnormal state information with the lowest storage priority is specified among the abnormal state information stored in the first to fourth unit areas 211a to 211d of the abnormal display area 211. The memory priority is predetermined in the design stage of the pachinko machine 10, and specifically, the lower tray 56a is full → the ball in the tank 75 is absent → vibration detection abnormality → dispensing abnormality by the dispensing device 76 → ball entry detection sensor 42a. The storage priority increases in the order of disconnection abnormality of 49a to radio wave detection abnormality. In the priority comparison process, one of the abnormal state information having the lowest storage priority stored in the first to fourth unit areas 211a to 211d and the abnormality display target generated this time has a higher storage priority. It is compared and judged.

If the storage priority of the abnormality display target that has occurred this time is lower (step S3305: NO), the abnormality display area 211 does not store information about the abnormality state that corresponds to the abnormality display target that has occurred this time. Accordingly, in a configuration in which the number of types of abnormality display targets is greater than the number of the first to fourth unit areas 211a to 211d provided in the abnormality display area 211, information on an abnormal state having a high storage priority is displayed. It is possible to leave it in the abnormality display area 211.

If the storage priority of the abnormality display target that occurred this time is higher (step S3305: YES), the setting processing of the abnormality display area 211 is executed (step S3306). In the setting process of the abnormality display area 211 that is executed when a positive determination is made in step S3305, the unit areas 211a to 211d specified as storing the information of the abnormal state having the lowest storage priority occur this time. The information of the abnormal state corresponding to the abnormal display target is overwritten.

On the other hand, when the value of the abnormality target counter in the main RAM 65 has not reached the maximum value (step S3303: NO), the value of the abnormality target counter is incremented by 1 (step S3307), and then the abnormality display area 211 is set. Is executed (step S3306). In the setting process, one area is selected from the unit areas 211a to 211d in which the abnormal state information is not stored in the abnormal display area 211, and the abnormal state corresponding to the abnormal display target that has occurred this time in the selected area is selected. Stores the information of.

In step S3306, if only one piece of abnormal state information is stored in the abnormal display area 211, the abnormal state information is stored in the first unit area 211a. If there is a plurality of pieces of abnormal state information stored in the above, the abnormal state information is stored in order from the area having the smallest value of "n" in the nth unit areas 211a to 211b.

In the abnormality setting process, it is determined whether or not an abnormal display target release event has occurred (step S3308). For example, whether or not a command indicating that the lower tray 56a is full, that the tank 75 is empty, or that the dispensing abnormality by the dispensing device 76 has been released is received from the dispensing side CPU 92. judge. In addition, whether or not the abnormality release operation for the occurrence of radio wave detection abnormality has been performed, whether the abnormality release operation for the occurrence of vibration detection abnormality has been performed, or whether the abnormality release operation for the occurrence of disconnection abnormality has been performed. judge.

If an affirmative decision is made in step S3308, an erasing process of the abnormality display area 211 is executed (step S3309). In the erasing process, it is specified whether or not the information on the abnormal state corresponding to the abnormal display target that is the current cancellation target is stored in any of the first to fourth unit areas 211a to 211d of the abnormal display area 211. If it is stored, the stored area is cleared to "0" to erase the information on the abnormal state. In this case, if only one piece of abnormal state information is stored in the abnormal display area 211 after erasing, the information of the abnormal state is stored in the first unit area 211a, and after erasing, the abnormal state information is stored. When there are a plurality of pieces of abnormal state information stored in the display area 211, the pieces of abnormal state information are stored in order from the area having the smallest “n” value in the nth unit areas 211a to 211b. Also, the value of the abnormality target counter of the main RAM 65 is decremented by 1 (step S3310).

In the abnormality setting process, it is determined whether or not an operation to start displaying an abnormality has occurred (step S3311). The start operation of the abnormality display is such that the setting state of the pachinko machine 10 can be changed and the game machine main body 12 is opened to the front with respect to the outer frame 11 in a non-changeable state, and the update button 68b is pressed. It is done by operating.

When an affirmative determination is made in step S3311, it is determined whether or not information on one or more abnormal states is stored in the abnormal display area 211 (step S3312). If the information on the abnormal state is not stored, the abnormal display on the first to fourth notification display devices 201 to 204 is not started. This makes it possible to prevent the abnormal display from being started even though there is no abnormal state information to be notified.

When an affirmative determination is made in step S3312, "1" is set to the abnormality display flag provided in the main RAM 65 (step S3313). The abnormal display flag stops the display corresponding to the management result of the game history, and displays the display corresponding to the abnormal state information stored in the abnormal display area 211 in the first to fourth notification display devices 201 to 204. This is a flag for the main CPU 63 to specify that the situation is to be performed in. Even if the abnormal display start operation is performed in a situation where the abnormal display flag is already set to "1", a negative determination is made in step S3311.

After that, the management result display stop setting process is executed (step S3314). In the cancellation setting process, a display cancellation command is transmitted to the management-side CPU 112 to temporarily cancel the update of the display of the management result of the game history on the first to fourth notification display devices 201 to 204. Upon receiving the display stop command, the management-side CPU 112 stops the display process (FIG. 55). However, the management-side CPU 112 does not set the display data to be the data of all “0” in the first to fourth display ICs 205 to 208 even if the display stop command is received. Therefore, until the display data is transmitted from the main CPU 63 to the first to fourth display ICs 205 to 208, the display of the management result of the game history at that time is continued on the first to fourth notification display devices 201 to 204. It

In the abnormality setting process, it is determined whether or not an operation for ending the abnormality display has occurred (step S3315). The operation of ending the abnormal display is performed by pressing the reset button 68c in a state where the gaming machine main body 12 is opened forward with respect to the outer frame 11 in a situation where the setting state of the pachinko machine 10 is not changeable. It is done by operating. If an affirmative decision is made in step S3315, the abnormal display flag in the main RAM 65 is cleared to "0" (step S3316). Even if the operation of ending the abnormal display is performed in the situation where the value of the abnormal display flag is "0", a negative determination is made in step S3315.

After that, the cancellation release process of displaying the management result is executed (step S3317). In the cancellation cancellation process, the cancellation cancellation command is transmitted to the management-side CPU 112 so that the update of the display of the management result of the game history on the first to fourth notification display devices 201 to 204 is canceled. To release. The management CPU 112 resumes the execution of the display process (FIG. 55) by receiving the cancellation cancel command. However, the management-side CPU 112 does not set the display data, which is the data of all “0”, in the first to fourth display ICs 205 to 208 even if the cancel release command is received. Therefore, until the display data is transmitted from the management CPU 112 to the first to fourth display ICs 205 to 208, the abnormal display at that time is continued on the first to fourth notification display devices 201 to 204. Further, the management side CPU 112 continues to store history information and calculate various parameters even in a situation where the update of the display of the game history management result is stopped, and the result of calculating various parameters is calculated. It is stored in the result memory 131. Therefore, when the state in which the update of the display of the management result of the game history is canceled is canceled, the display of the latest management result of the game history is immediately displayed on the first to fourth notification display devices 201 to 204. It will be restarted.

In the abnormality setting process, if "1" is set in the abnormality display flag of the main RAM 65 (step S3318: YES), the abnormality display process is executed (step S3319). FIG. 64 is a flowchart showing the abnormality display processing.

First, the extinguishing process of the first and second notification display devices 201 and 202 is executed (step S3401). Specifically, the display data that is all “0” is output to the first and second display ICs 205 and 206. As a result, all the display segments of the first and second notification display devices 201 and 202 are turned off, and the first and second notification display devices 201 and 202 are hidden.

Then, the value of the update timing counter provided in the main RAM 65 is decremented by 1 (step S3402). The update timing counter is a counter for the main CPU 63 to specify that it is the time to update the display content of the abnormal display on the first to fourth notification display devices 201 to 204. If the value of the update timing counter is already "0", that state is maintained. After that, by determining whether or not the value of the update timing counter is “0”, it is determined whether or not it is time to update the display contents of the first to fourth notification display devices 201 to 204 ( Step S3403).

If an affirmative decision is made in step S3403, an updating process of the display target counter provided in the main RAM 65 is executed (step S3404). In the update processing, if the current abnormal display processing has been performed for the first time since the abnormal display flag of the main RAM 65 was set to "1" this time, the display target counter is set to "0". The value of the display target counter corresponds to the first to fourth unit areas 211a to 211d of the abnormality display area 211, and specifically, the value of "0" of the display target counter corresponds to the first unit area 211a. The display target counter “1” value corresponds to the second unit area 211b, the display target counter “2” value corresponds to the third unit area 211c, and the display target counter “3”. The value of “” corresponds to the fourth unit area 211d. In the update processing, the value of the display target counter is incremented by 1 if this is not the first processing time of the abnormality display processing after the abnormality display flag of the main RAM 65 is set to "1".

After that, it is determined whether or not the information of the abnormal state is stored in the area corresponding to the current value of the display target counter among the first to fourth unit areas 211a to 211d (step S3405). Here, as described above, when only one piece of abnormal state information is stored, the abnormal state information is stored in the first unit area 211a, and a plurality of abnormal state information is stored. In this case, the abnormal state information is stored in order from the area having the smallest “n” value in the nth unit areas 211a to 211b. Therefore, when the abnormal state information is not stored in the area corresponding to the current value of the display target counter, the abnormal state information is also stored in the area corresponding to the value larger than the value of the display target counter. There will be no. Further, when the value of the display target counter after adding 1 exceeds the maximum value “3”, since the corresponding area does not exist in the first place, the information on the abnormal state is treated as not stored. ..

If an affirmative decision is made in step S3405, the value of the display target counter of the main RAM 65 is cleared to "0" (step S3406). Here, it is assumed that all the abnormal states that are the targets of the abnormal display are canceled in the situation where the abnormal display is being performed. In this case, even if the abnormal display processing is executed, the abnormal display area 211 does not store the abnormal state information. In such a situation, a display indicating that the information on the abnormal state is not stored is displayed on the third and fourth notification display devices 203 and 204.

If a negative determination is made in step S3405, or if the processing of step S3406 is executed, display data of the display target corresponding to the value of the display target counter of the main RAM 65 is read from the main ROM 64 (step S3407). Specifically, the information stored in the area corresponding to the value of the display target counter of the main RAM 65 among the first to fourth unit areas 211a to 211d of the abnormality display area 211 is read. Then, the display data corresponding to the information is read from the main ROM 64. The display data is set in a one-to-one correspondence with the abnormal state information, and the display contents of the third and fourth notification display devices 203 and 204 based on the display data are set for each type of abnormal state information. It's different. There is also display data corresponding to the absence of abnormal state information, and this display data is different from the display data corresponding to the abnormal state information. Therefore, when the abnormal state information does not exist, the display contents of the third and fourth notification display devices 203 and 204 have different display contents from those when the abnormal state information exists.

On the other hand, the display content of the display corresponding to the information of the abnormal state and the display content of the display corresponding to the absence of the information of the abnormal state on the third and fourth notification display devices 203 and 204 are the third and the third. The display contents when displaying the management result of the game history on the fourth notification display devices 203 and 204 and the display contents of the set value on the fourth notification display device 204 overlap. On the other hand, when displaying the management result of the game history, all of the first to fourth notification display devices 201 to 204 are in the display state, and the setting state of the pachinko machine 10 can be changed. In the state, the first to third notification display devices 201 to 203 are in the non-display state and the fourth notification display device 204 is in the display state, and when the abnormal display is performed, the first and second notification display devices Since 201 and 202 are in the non-display state and the third and fourth notification display devices 203 and 204 are in the display state, even if the display contents are duplicated as described above, any situation can be dealt with. It becomes possible for the manager of the game hall to know whether the display is displayed.

After that, the display of the third notification display device 203 is controlled according to the display data read in step S3407 (step S3408), and the display control of the fourth notification display device 204 is controlled (step S3409). In this case, the third annunciator display device 203 and the fourth annunciator display device 203 are used regardless of whether the information corresponding to the abnormal state information is displayed or the information corresponding to the absence of the abnormal state information is displayed. None of the display devices 204 are in the non-display state (that is, are not in the all-off state), and are in some display state.

After that, a value corresponding to 2 seconds is set in the update timing counter of the main RAM 65 as a value corresponding to the next update timing (step S3410).

According to this embodiment described in detail above, the following excellent effects are exhibited.

In the configuration in which the management result of the game history is displayed on the first to fourth notification display devices 201 to 204, the display corresponding to the abnormal state of the pachinko machine 10 is displayed on the first to fourth notification display devices 201 to 204. Is done. As a result, it becomes possible to use the first to fourth notification display devices 201 to 204 not only for displaying the management result of the game history but also as a display device for performing a display corresponding to the abnormal state.

In the case where the first to fourth notification display devices 201 to 204 are caused to perform the display corresponding to the abnormal condition when the pachinko machine 10 is not in the abnormal condition, the first to fourth notification display devices 201 to 204 A display corresponding to that no abnormal condition has occurred is displayed. This makes it possible to clearly specify whether or not the pachinko machine 10 is in an abnormal state by checking the first to fourth notification display devices 201 to 204.

The period corresponding to the period in which the game history management result is displayed on the first to fourth notification display devices 201 to 204 and the display corresponding to the abnormal state of the pachinko machine 10 are displayed on the first to fourth notification display devices 201 to 204. It is distinguished from the period during which it is opened. Accordingly, by grasping the situation in which the display is performed on the first to fourth notification display devices 201 to 204, which display is performed on the first to fourth notification display devices 201 to 204. It becomes possible to specify whether or not there is.

When the display corresponding to the abnormal state of the pachinko machine 10 is performed, the first to fourth notification display devices 201 to 204 have different display modes from the display mode when the game history management result is displayed. Display controlled. Accordingly, by grasping the display modes of the first to fourth notification display devices 201 to 204, it is possible to identify which display is being performed on the first to fourth notification display devices 201 to 204. It becomes possible.

A plurality of notification display devices 201 to 204 are provided. As a result, a wide variety of displays can be performed as the display corresponding to the management result of the game history. In addition, due to the presence of the plurality of display devices 201 to 204 for notification, the display mode is large when the management result of the game history is displayed and when the display corresponding to the abnormal state of the pachinko machine 10 is performed. It is possible to make a difference.

When the display corresponding to the abnormal state of the pachinko machine 10 is performed, the first and second notification display devices 201 and 202 that are not in the non-display state when displaying the management result of the game history are in the non-display state. Thereby, the display of the management result of the game history and the display corresponding to the abnormal state of the pachinko machine 10 are performed only by confirming whether or not the first and second notification display devices 201 and 202 are in the non-display state. It is possible to clearly specify which one of them is performed by the first to fourth notification display devices 201 to 204.

When the display corresponding to the abnormal state of the pachinko machine 10 is performed, the third and fourth notification display devices 203 and 204 are in the display state, and the display content is the third when the game history management result is displayed. , Display contents that can be displayed on the fourth notification display devices 203 and 204. In this way, the display contents on the third and fourth notification display devices 203 and 204 are allowed to overlap with each other, so that the case where the management result of the game history is displayed and the display corresponding to the abnormal state of the pachinko machine 10 are displayed. It is possible not to give a restriction to each display content when it is performed. Even if the display contents on the third and fourth notification display devices 203 and 204 can be duplicated as described above, if the display corresponding to the abnormal state of the pachinko machine 10 is performed, the first, first Since the second notification display devices 201 and 202 are in the non-display state, it is possible to specify which display is being performed on the first to fourth notification display devices 201 to 204.

In addition, when the operation for starting the abnormality display is performed in a situation where the information on the abnormal state is not stored in the abnormality display area 211, the information on the abnormal state is displayed on the first to fourth notification display devices 201 to 204 at that time. May be configured to be displayed corresponding to the fact that is not stored.

<Fourteenth Embodiment>
In the present embodiment, the processing configuration of the management output processing executed by the main CPU 63 is different from that of the first embodiment. The configuration different from that of the first embodiment will be described below. The description of the same configuration as that of the first embodiment is basically omitted.

FIG. 65 is a flowchart showing the management output process executed by the main CPU 63 in this embodiment.

First, it is determined whether or not "1" is set in the management start flag provided in the main RAM 65 (step S3501). The management start flag is a flag for the main CPU 63 to specify whether or not the history information should be stored in the history memory 117. In this embodiment, the total number of game balls discharged from the game area PA after the supply of the operating power to the pachinko machine 10 is started (that is, after the supply of the operating power to the MPU 62 is started) is the management start criterion. If the total number of game balls discharged from the game area PA is equal to or larger than the management start reference value, the history information is not stored in the memory 117 for history until the number becomes equal to or more than the value. The storage of history information in the history memory 117 is started. At the shipping stage of the pachinko machine 10 or the like, the operation check of the pachinko machine 10 may be performed before shipping, in which case the game ball is cared for in each ball entry portion and the subsequent operation is checked. On the other hand, after the start of the supply of the operating power to the pachinko machine 10, the history information is not stored in the history memory 117 until the total number of the game balls discharged from the game area PA becomes the management start reference value or more. By doing so, it is possible to prevent the result of entering the ball during the above-described operation check from being stored as history information.

When a negative determination is made in step S3501, "7" is set to the start time management counter provided in the main RAM 65 (step S3502). The start-time management counter indicates which of the seven ball-entry detection sensors 42a to 48a is in the situation in which the detection state of the game ball is specified in the situation where "1" is not set in the management start flag. This is a counter for the main CPU 63 to specify.

After that, it is determined whether or not the output flag of the main RAM 65 corresponding to the value of the start time management counter is set to "1" (step S3503). Specifically, when the value of the start-time management counter is "7" and corresponds to the first winning hole detection sensor 42a, it is determined whether "1" is set in the first output flag. If the value of the start time management counter is "6" and it corresponds to the second winning opening detection sensor 43a, it is determined whether or not "1" is set in the second output flag, and the start time management is performed. When the value of the counter is "5" and corresponds to the third winning hole detection sensor 44a, it is determined whether or not "1" is set in the third output flag, and the value of the start management counter is When it is "4" and corresponds to the special electric power detection sensor 45a, it is determined whether or not the fourth output flag is set to "1", and the value of the start-time management counter is "3" and the first When it corresponds to the working port detection sensor 46a, it is determined whether or not the fifth output flag is set to "1", and the value of the start time management counter is "2", and the second working port detection sensor is detected. If it corresponds to 47a, it is judged whether or not the sixth output flag is set to "1", and if the value of the start management counter is "1" and it corresponds to the outlet 24a. Determines whether "1" is set in the seventh output flag. As described above, the first to seventh output flags are set to "1" in the incoming ball detection process (FIG. 15).

If an affirmative decision is made in step S3503, the output flag corresponding to the value of the start-time management counter is cleared to "0" (step S3504). After that, the value of the discharged number counter provided in the main RAM 65 is incremented by 1 (step S3505). The discharge number counter is a counter for the main CPU 63 to specify the total number of game balls discharged from the game area PA in a situation where “1” is not set in the management start flag of the main RAM 65.

After that, it is determined whether or not the value of the discharged number counter is equal to or larger than the management start reference value (step S3506). Although the management start reference value is set to "300", the present invention is not limited to this, and the number may be smaller than "300" or may be larger than "300". ..

When a negative determination is made in step S3503 or when a negative determination is made in step S3506, the value of the start-time management counter of the main RAM 65 is decremented by 1 (step S3507). Then, it is determined whether or not the value of the start management counter after subtracting 1 is "0" (step S3508). When a negative determination is made in step S3508, the process returns to step S3503, and when an affirmative determination is made in step S3508, the output process for management ends as it is.

On the other hand, when the value of the discharge number counter of the main RAM 65 is equal to or larger than the management start reference value (step S3506: YES), the management start flag of the main RAM 65 is set to "1" (step S3509). After that, the management process is executed (step S3510). Also, when the management start flag is set to "1" and an affirmative judgment is made in step S3501, the management process is executed (step S3510). The processing content of the management process is the same as steps S1001 to S1012 of the management output process (FIG. 25) in the first embodiment.

According to the above configuration, the total number of game balls discharged from the game area PA is managed after the supply of the operating power to the pachinko machine 10 is started (that is, after the supply of the operating power to the MPU 62 is started). The history information is not stored in the history memory 117 until the number of game balls is equal to or larger than the start reference value, and the total number of game balls discharged from the game area PA is equal to or larger than the management start reference value. In this case, the storage of history information in the history memory 117 is started. At the shipping stage of the pachinko machine 10 or the like, the operation check of the pachinko machine 10 may be performed before shipping, in which case the game ball is cared for in each ball entry portion and the subsequent operation is checked. On the other hand, after the start of the supply of the operating power to the pachinko machine 10, the history information is not stored in the history memory 117 until the total number of the game balls discharged from the game area PA becomes the management start reference value or more. By doing so, it is possible to prevent the result of entering the ball during the above-described operation check from being stored as history information.

Here, for history until the total number of game balls discharged from the game area PA after the supply of the operating power to the pachinko machine 10 is started becomes equal to or more than the number corresponding to the management start reference value. In the configuration in which the history information is not stored in the memory 117, the management result of the game history during that period cannot be calculated. Therefore, in such a situation, the display corresponding to the situation may be performed on the first to fourth notification display devices 201 to 204. For example, all the display segments in each of the first to fourth notification display devices 201 to 204 may be in a light emitting state. Since the display content is not displayed either when the management result of the game history is displayed or when it is displayed that the setting state of the pachinko machine 10 is changeable, By checking the first to fourth notification display devices 201 to 204, it is possible to specify whether or not the history information is not stored as described above.

Note that the setting mode of the information of the management start flag of the main RAM 65 differs depending on whether or not the setting state of the pachinko machine 10 can be changed after the start of supplying the operating power to the pachinko machine 10. It may be configured to. FIG. 66 is a flowchart showing a main process in the another mode executed by the main CPU 63. In steps S3601 to S3609, the same processing as steps S101 to S109 of the main processing (FIG. 9) in the first embodiment is executed, and in steps S3611 to S3620, the main processing in the first embodiment (FIG. The same processing as steps S110 to S119 of 9) is executed. On the other hand, in this another embodiment, when the affirmative determination is made in step S3608, the management start flag of the main RAM 65 is cleared to “0” (step S3610), and the management start flag of the main RAM 65 is executed after executing the processing of step S3620. Is set to "1" (step S3621). According to the configuration, when the process for newly setting the setting state of the pachinko machine 10 is not executed, the total number of game balls discharged from the game area PA after the supply of the operating power to the pachinko machine 10 is started. The history information is not stored in the history memory 117 until is greater than or equal to the management start reference value, and when a process for newly setting the setting state of the pachinko machine 10 is executed, History information is stored in the history memory 117 regardless of the number of discharged game balls after the start of supplying the operating power. As a result, in a situation where it is highly unlikely that the operation check at the shipping stage of the pachinko machine 10 is likely to occur, it becomes possible to manage the game history immediately after the start of supplying the operating power to the pachinko machine 10.

Further, the history information is stored in the history memory 117 until the total number of game balls discharged from the game area PA becomes equal to or more than the management start reference value after the supply of the operating power to the pachinko machine 10 is started. Instead of the non-history structure, an area for storing history information may be provided separately from the history memory 117 until the total number of game balls exceeds a management start reference value. Thereby, it becomes possible to specify the management result of the game history in the situation.

Further, the history information is stored in the history memory 117 until the total number of game balls discharged from the game area PA becomes equal to or more than the management start reference value after the supply of the operating power to the pachinko machine 10 is started. As a condition under which a situation does not exist, a configuration may be added in which a condition that the supply of operating power to the pachinko machine 10 is started in a situation where history information is not stored in the history memory 117 is added. In this case, when the supply of operating power to the pachinko machine 10 is started in a situation where history information is already stored in the history memory 117, the total number of game balls discharged from the game area PA is the management start criterion. The history information is stored in the history memory 117 from the beginning regardless of whether or not the value is greater than or equal to the value.

Further, the history information is stored in the history memory 117 until the total number of game balls discharged from the game area PA becomes equal to or more than the management start reference value after the supply of the operating power to the pachinko machine 10 is started. In addition to or instead of the non-existing configuration, when an abnormal state such as a radio wave detection abnormality or a vibration detection abnormality occurs, the history information may not be stored in the history memory 117 until the abnormal state is canceled. As a result, it becomes possible to prevent the history information from being stored for an event that occurred in an abnormal state.

Further, the history information is stored in the history memory 117 until the total number of game balls discharged from the game area PA becomes equal to or more than the management start reference value after the supply of the operating power to the pachinko machine 10 is started. In addition to or instead of the non-existent configuration, history information may not be stored in the history memory 117 when the gaming machine body 12 or the front door frame 14 is open. This makes it possible to prevent history information from being stored for an event that occurred in a situation where the gaming machine main body 12 or the front door frame 14 is open.

<Fifteenth Embodiment>
In this embodiment, the execution subject of the process for managing the game history is different from that of the first embodiment. The configuration different from that of the first embodiment will be described below. The description of the same configuration as that of the first embodiment is basically omitted.

Although the MPU 62 is provided with the management IC 66 in the first embodiment, the MPU 62 is not provided with the management IC 66 in the present embodiment. Instead of the management IC 66 being provided, in the present embodiment, processing for managing the game history is executed by the main CPU 63. Further, in the present embodiment, the main CPU 63 executes various controls by distinguishing between specific control and non-specific control. Specifically, the control relating to the management of the game history is the non-specific control, and the control other than the non-specific control including the control for advancing the game based on the game operation by the player is the specific control.

Regarding the specific control in detail, all the control by the main process (FIG. 9) executed when the supply of the operating power to the main CPU 63 is started is included in the specific control. In the present embodiment, the recognition process (step S111), the data output process (step S112), and the set value update signal output process (step S119) of the main process (FIG. 9) in the first embodiment are performed. Not executed Further, even in the present embodiment, the timer interrupt processing is executed periodically so as to interrupt the processing of steps S113 to S116 in the main processing (FIG. 9). Of these, all the processes other than the management process described later are included in the specific control. Part of the management process is also included in the specific control.

FIG. 67 is an explanatory diagram for explaining a setting mode of programs and data in the main ROM 64. Corresponding to the fact that the control executed by the main CPU 63 is distinguished between the specific control and the non-specific control, as shown in FIG. 67, the main ROM 64 also has a specific control program and a specific control program. The addresses of the areas in which the data and the program for non-specific control and the data for non-specific control are stored are clearly distinguished.

Specifically, the programs for specific control are collectively stored in the area of each continuous address within the range of addresses X(1) to X(k+2). Further, the addresses X(k+3) to X(k+5) that are consecutive to the addresses X(1) to X(k+2) are addresses of an unused area in which no data is stored, and the address X( Data for specific control is collectively stored in the area of each continuous address within the range of k+6) to X(m+2). Further, the addresses X(m+3) to X(m+5) which are consecutive to the addresses X(k+6) to X(m+2) are addresses of an unused area in which no data is stored, and the address X( Programs for non-specific control are collectively stored in the area of each continuous address in the range of m+6) to X(n+2). Further, the addresses X(n+3) to X(n+5), which are consecutive to the addresses X(m+6) to X(n+2), are the addresses of unused areas in which no data is stored, and the address X( The data for non-specific control are collectively stored in the area of each continuous address within the range of (n+6) to X(p+2). The relationship between the program and data and the address as described above is set in both the physical address in the main ROM 64 and the logical address on the memory map recognized by the main CPU 63.

As described above, the program for specific control and the data for specific control, and the program for non-specific control and the data for non-specific control, regardless of the execution order of the process for executing the corresponding control, Since the addresses are stored in the areas of different ranges, for example, when checking only the program for specific control and the data for specific control, the address where the program for specific control and the data for specific control are stored. Only the area of the range needs to be checked. For example, when checking only the program for non-specific control and the data for non-specific control, the address where the program for non-specific control and the data for non-specific control are stored. You only have to check the area of the range. Therefore, it is possible to efficiently perform the work for checking the program and the data by distinguishing between the specific control and the non-specific control. Further, accordingly, it becomes possible to efficiently perform the work when the program and the data are modified by distinguishing between the specific control and the non-specific control.

No data is stored between the address range of the area storing the program for specific control and the data for specific control and the address range of the area storing the program for non-specific control and the data for non-specific control Since the address range of the unused area which is not set is set, the boundary between the address range for specific control and the address range for non-specific control can be easily grasped during the check work.

In each of the address range for specific control and the address range for non-specific control, programs and data are stored in areas of addresses of different ranges regardless of the execution order of the processing for executing the corresponding control. By doing so, it becomes possible to efficiently perform the work for checking the program and the data separately. In addition, since the address range of the unused area where no data is stored is set between the address range of the area where the program is stored and the address range of the area where the data is stored, It becomes easy to understand the boundary between the address range and the address range of the data when checking.

FIG. 68 is an explanatory diagram for explaining a setting mode of each area in the main RAM 65. Corresponding to the fact that the control executed by the main CPU 63 is divided into specific control and non-specific control, as shown in FIG. 68, the main RAM 65 also has a work area 221 for specific control and a specific control. The address range of the stack area 222 for non-specific control and the address range of the work area 223 for non-specific control and the stack area 224 for non-specific control are clearly distinguished.

Specifically, the area of each successive address within the range of addresses Y(1) to Y(r+2) is set as the work area 221 for specific control. Further, the addresses Y(r+3) to Y(r+5) that are continuous with the addresses Y(1) to Y(r+2) are the addresses of the unused areas, and subsequently, the addresses Y(r+6) to Y(s+2). The area of each continuous address within the range of () is set as the stack area 222 for specific control. Addresses Y(s+3) to Y(s+5), which are continuous with addresses Y(r+6) to Y(s+2), are addresses of unused areas, and are followed by addresses Y(s+6) to Y(t+2). The area of each consecutive address within the range of () is set as the work area 223 for non-specific control. Further, addresses Y(t+3) to Y(t+5) consecutive to the addresses Y(s+6) to Y(t+2) are addresses of unused areas, and subsequently, addresses Y(t+6) to Y(u+2). The area of each continuous address within the range of () is set as the stack area 224 for non-specific control. The relationship between each area and the address as described above is set in both the physical address in the main RAM 65 and the logical address on the memory map recognized by the main CPU 63.

When the work area 221 for specific control and the work area 223 for non-specific control are set separately as described above, the main CPU 63 executes the specific control and the non-specific control is executed. Thus, different areas of the main RAM 65 are used when various calculations are executed. As a result, when one of the specific control and the non-specific control is executed, it is possible to make it difficult for an event such that the information in the main RAM 65 necessary for the other is erased. Incidentally, when writing information to each work area 221, 223 and reading information from each work area 221, 223, the main CPU 63 issues a load instruction.

Since the stack area 222 for the specific control and the stack area 224 for the non-specific control are separately set, the main CPU 63 can perform the specific control and the non-specific control by the main CPU 63. Different areas of the main RAM 65 are used when the information stored in the register of the side CPU 63 is saved and when the information of the return address on the program is stored. As a result, in the case where one of the specific control and the non-specific control is being executed, the information stored in the register of the main CPU 63 is saved and the information of the return address on the program is stored. It is possible to make it difficult for an event such as the deletion of the stored information to occur. Incidentally, when writing information to the stack areas 222 and 224, a push command is issued by the main CPU 63, and when reading information from the stack areas 222 and 224, a pop instruction is issued by the main CPU 63. Further, when reading information from the stack areas 222 and 224, the order of writing to the stack areas 222 and 224 is to be read first after the later information.

Here, when the main CPU 63 executes a process corresponding to the specific control, the main CPU 63 can write information to the work area 221 for the specific control and the stack area 222 for the specific control, and Information can be read from the specific control work area 221 and the specific control stack area 222. On the other hand, when the main CPU 63 executes a process corresponding to the specific control, the main CPU 63 can read information from the non-specific control work area 223 and the non-specific control stack area 224. Information cannot be written in the work area 223 for non-specific control and the stack area 224 for non-specific control. This makes it possible to prevent the information used in the process corresponding to the non-specific control from being accidentally erased in the situation where the process corresponding to the specific control is being executed.

When the main CPU 63 executes a process corresponding to the non-specific control, the main CPU 63 can write information in the work area 223 for non-specific control and the stack area 224 for non-specific control. At the same time, it is possible to read information from the work area 223 for non-specific control and the stack area 224 for non-specific control. On the other hand, when the main CPU 63 executes a process corresponding to the non-specific control, the main CPU 63 can read information from the specific control work area 221 and the specific control stack area 222. It is impossible to write information to the work area 221 for specific control and the stack area 222 for specific control. This makes it possible to prevent the information used in the process corresponding to the specific control from being accidentally deleted in the situation where the process corresponding to the non-specific control is being executed.

The backup power is supplied to the main RAM 65 even after the power supply to the pachinko machine 10 is cut off. The backup power is supplied to the work area 221 for specific control, the stack area 222 for specific control, and the non-specific control. Are supplied to all of the work area 223 for stacking and the stack area 224 for non-specific control. As a result, the information stored in the specific control work area 221, the specific control stack area 222, the non-specific control work area 223, and the non-specific control stack area 224 is turned off by the pachinko machine 10. Even after that, the data is retained while the backup power is being supplied.

Next, the timer interrupt processing in this embodiment executed by the main CPU 63 will be described with reference to the flowchart in FIG. Similar to the first embodiment, the timer interrupt process is executed periodically (for example, every 4 milliseconds) in a situation where the processes of steps S113 to S116 are executed in the main process (FIG. 9). The program corresponding to the timer interrupt process is set to the program for specific control.

In steps S3701 to S3718, the same processing as steps S301 to S318 of the timer interrupt processing (FIG. 11) in the first embodiment is executed. These processes are executed by the main CPU 63 using a specific control program and specific control data. In step S3719 of the timer interrupt processing, management processing is executed. When the management process is executed, the subroutine program corresponding to the management process set in the specific control program is executed. The information for specifying the return address of the timer interrupt process in is written in the stack area 222 for specific control by the push command. When the management process ends, the pop instruction reads the information for specifying the return address, and the program returns to the timer interrupt processing program indicated by the return address.

FIG. 70 is a flowchart showing the management process. The processes of steps S3801 to S3805 in the management process are executed by the main CPU 63 using the specific control program and the specific control data.

First, interrupt prohibition is set in order to prohibit the occurrence of timer interrupt processing (FIG. 69) (step S3801). This prevents the timer interrupt process (FIG. 69), which is a process corresponding to the specific control, from being interrupted and activated in the middle of a management execution process, which will be described later, which is a process corresponding to the non-specific control. Is possible.

After that, as "PUSH PSW", the information in the flag register of the main CPU 63 is saved in the stack area 222 for specific control by a push command (step S3802). The flag register includes a carry flag, a zero flag, a P/V flag, a sine flag, a half carry flag, etc., and the information in the flag register changes depending on the execution result of an arithmetic instruction, a rotate instruction, an input/output instruction, and the like. By saving such information in the flag register before the program of the subroutine corresponding to the management execution process is started, the information in the flag register in the state before the change of the call of the subroutine or the start of the subroutine is saved. It is possible to save it in the stack area 222 for specific control. The information amount of the flag register is 1 byte.

After that, the management execution process is started by reading the program of the subroutine corresponding to the management execution process set in the non-specific control program (step S3803). In this case, the information for specifying the return address of the management process after the execution of the management execution process is written in the stack area 222 for specific control by the push command. Then, when the management execution processing is completed, the information for specifying the return address is read by the pop command, and the program for the management processing indicated by the return address is returned to.

When returning to the management processing program after execution of the management execution processing, the information of the flag register saved in the stack area 222 for specific control in step S3802 by the pop command as “POP PSW” is used as the main CPU 63. The flag register is reset (step S3804). As a result, the information in the flag register of the main CPU 63 is restored to the information at the time when step S3802 was executed. That is, the information in the flag register of the main CPU 63 is restored to the information for executing the specific control.

After that, the interrupt permission is set to switch from the state in which the generation of the timer interrupt process (FIG. 69) is prohibited to the state in which the generation is permitted (step S3805). This enables a new execution of the timer interrupt process.

FIG. 71 is a flowchart showing the management execution process. The processes of steps S3901 to S3915 in the management execution process are executed by the main CPU 63 using the non-specific control program and the non-specific control data.

First, as "LDSP, Y(u+2)", a load instruction sets Y(u+2) as a fixed address at the start of the non-specific control in the stack pointer of the main CPU 63 (step S3901). The stack pointer is an area in which information on an address for specifying, in the stack areas 222 and 224, a storage area to which information is to be written by a push command is specified by the main CPU 63. Each time a push instruction is performed, the stack pointer information is updated to the address information of the storage area to be written in the next order, and each time a pop instruction is issued, the stack pointer information is written in the previous order. The information of the address of the storage area is updated. When the stack area 224 for non-specific control is used, the information to be stored is stored from the storage area of the last address in the stack area 224 for non-specific control, and every time the information to be stored is added. Further, the storage area of the storage destination is changed toward the first address side in the stack area 224 for non-specific control. Therefore, in step S3901, the information of the last address in the stack area 224 for non-specific control is set in the stack pointer. As described above, the information is stored from the storage area of the last address to the storage area of the first address also in the stack area 222 for specific control.

By the way, for both the stack area 222 for specific control and the stack area 224 for non-specific control, when a push command is additionally executed despite the information being set in all storage areas, All areas of the main RAM 65 are cleared to "0" as an abnormality in the storage processing. As a result, it is possible to prevent the game from proceeding as it is even though an abnormality occurs in the storage process.

After that, as "LD (_WABUF), WA", the information of the WA register of the main CPU 63 is saved in the WA buffer set in the work area 223 for non-specific control by a load instruction (step S3902). Further, as "LD (_BCBUF), BC", the load instruction saves the information in the BC register of the main CPU 63 to the BC buffer set in the work area 223 for non-specific control (step S3903). Further, as "LD (_DEBUF), DE", the information of the DE register of the main CPU 63 is saved in the DE buffer set in the work area 223 for non-specific control by a load instruction (step S3904). As "LD (_HLBUF), HL", the load instruction saves the information in the HL register of the main CPU 63 to the HL buffer set in the work area 223 for non-specific control (step S3905). Also, as "LD (_IXBUF), IX", the load instruction saves the information in the IX register of the main CPU 63 to the IX buffer set in the work area 223 for non-specific control (step S3906). Further, as "LD (_IYBUF), IY", the information of the IY register of the main CPU 63 is saved in the IY buffer set in the work area 223 for non-specific control by a load instruction (step S3907).

In addition to the flag register already described, various general-purpose registers, auxiliary registers, and index registers exist in the registers of the main CPU 63. In this case, in steps S3902 to S3907, each information of the WA register, BC register, DE register, HL register, IX register, and IY register, which is a part of these various general-purpose registers, auxiliary registers, and index registers, is used. Are saved in the corresponding buffer in the work area 223 for non-specific control. The WA register, the BC register, the DE register, the HL register, the IX register, and the IY register each have an information amount of 2 bytes.

The WA register, BC register, DE register, HL register, IX register, and IY register are registers used in the check process (step S3908) corresponding to the non-specific control. By saving the information set in such registers in the work area 223 for non-specific control before executing the check process (step S3908), the information in these registers used in the specific control is controlled by non-specific control. It is possible to evacuate before the start of. Therefore, even if these registers are overwritten in the non-specific control, the information saved in the work area 223 for the non-specific control is restored to these registers when the non-specific control is finished, so that the states of these registers can be restored. Can be returned to the state corresponding to the specific control before the non-specific control is executed.

Further, instead of saving all information of various general-purpose registers, auxiliary registers, and index registers in the work area 223 for non-specific control, the WA to be used in the check process corresponding to the non-specific control is used. Register information is saved in the work area 223 for non-specific control by selectively saving information in the register, BC register, DE register, HL register, IX register, and IY register to the work area 223 for non-specific control. Therefore, it becomes possible to suppress the capacity to be secured. Therefore, it is possible to save the information in the register as described above while securing a large capacity of the work area 223 for non-specific control that can be used in the check processing. Of course, various general-purpose registers, auxiliary registers, and index registers in the main CPU 63 other than the WA register, BC register, DE register, HL register, IX register, and IY register are compatible with non-specific control. The information set before the processing to be performed is stored and held until the processing corresponding to the non-specific control ends and the processing corresponding to the specific control is restarted.

Further, the register information is not saved in the non-specific control stack area 224 but is saved in the non-specific control work area 223, so that the capacity of the non-specific control stack area 224 can be reduced to that extent. It will be possible. Further, when the stack area 224 for non-specific control is used, the writing order of information is read first from the later information as described above. Therefore, the reading order of information is displaced due to some noise or the like. If this happens, all subsequent read order information will be restored to a different register. The probability of occurrence of such an event increases as the amount of information saved in the stack area 224 for non-specific control increases. On the other hand, by saving the information in the register in the work area 223 for non-specific control, it is possible to prevent the above event from occurring even when there is a large amount of information to be saved. ..

After executing the processes of steps S3902 to S3907, the check process is executed (step S3908). When the check process is executed, the subroutine program corresponding to the check process set in the non-specific control program is executed. However, when executing the subroutine program, the management after the check process is executed. Information for specifying the return address of the execution process is written in the stack area 224 for non-specific control by the push command. When the check processing is completed, the pop instruction reads the information for specifying the return address, and the program returns to the management execution processing program indicated by the return address. Details of the check processing will be described later.

After executing the check process, Y(r+α) is set as the fixed address at the time of returning to the specific control to the stack pointer of the main CPU 63 by the load instruction as “LDSP, Y(r+α)” (step S3909). ). The address of Y(r+α) is set as an address between Y(r+8) and Y(s) in the stack area 222 for specific control.

The amount of information stored in the stack area 222 for specific control is always constant immediately before the subroutine of the management execution processing is executed in step S3803 of the management processing (FIG. 70). The information of the stack pointer of the side CPU 63 (that is, the value of the stack pointer) is constant. In this case, as the information stored in the stack area 222 for specific control, for example, the information on the return address of the management process (FIG. 70) after the management execution process (FIG. 71) and the management process ( Information on the return address of the timer interrupt process (FIG. 69) after the end of FIG. 70) can be given. The constant information of the stack pointer is Y(r+α). Therefore, when the check process, which is the process corresponding to the non-specific control, is completed and the process is returned to the process corresponding to the specific control, Y(r+α), which is the certain information, is set in the stack pointer of the main CPU 63. As a result, the information of the stack pointer can be restored to the information immediately before the process corresponding to the non-specific control is started. By setting the fixed information in the stack pointer in this way to restore the information of the stack pointer to the information immediately before the process corresponding to the non-specific control is started, the process corresponding to the non-specific control is performed. It is not necessary to save the information of the stack pointer of the main CPU 63 corresponding to the specific control in the main RAM 65 before starting. Therefore, it is possible to reduce the processing load, and it is not necessary to secure an area for saving in the main RAM 65.

After that, the information saved in the WA buffer of the work area 223 for non-specific control is overwritten in the WA register of the main CPU 63 by the load instruction as "LD WA, (_WABUF)" (step S3910). Further, as "LD BC, (_BCBUF)", the information saved in the BC buffer of the work area 223 for non-specific control is overwritten in the BC register of the main CPU 63 by the load instruction (step S3911). Further, as "LD DE, (_DEBUF)", the information saved in the DE buffer of the work area 223 for non-specific control is overwritten in the DE register of the main CPU 63 by the load instruction (step S3912). Further, as "LD HL,(_HLBUF)", the load instruction overwrites the information saved in the HL buffer of the work area 223 for non-specific control in the HL register of the main CPU 63 (step S3913). Further, as "LD IX, (_IXBUF)", the information saved in the IX buffer of the work area 223 for non-specific control is overwritten in the IX register of the main CPU 63 by the load instruction (step S3914). Further, as "LDIY, (_IYBUF)", the information saved in the IY buffer of the work area 223 for non-specific control is overwritten in the IY register of the main CPU 63 by the load instruction (step S3915). By executing the processing in steps S3910 to S3915, processing corresponding to non-specific control is started for each information of the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63. It is possible to restore the information corresponding to the specific control immediately before.

Here, the information stored in the flag register and various registers of the main CPU 63 when the process corresponding to the non-specific control is executed is not saved in the main RAM 65 when the process corresponding to the specific control is restarted. .. As a result, there is no need to secure a storage area for saving the above information in the specific control work area 221 and the specific control stack area 222.

Further, when the processing corresponding to the non-specific control is executed, the information stored in the flag register and the various registers of the main CPU 63 has the processing corresponding to the non-specific control after returning to the processing corresponding to the specific control. This information is not used when it is restarted. That is, the information necessary for a plurality of processing times of the processing corresponding to the non-specific control executed with the processing corresponding to the specific control interposed therebetween is the work area 223 for the non-specific control or the stack area for the non-specific control. 224, and is not stored in the flag register and various registers of the main CPU 63. Therefore, even if the information stored in the flag register and various registers of the main CPU 63 is not saved in the main RAM 65 when the process corresponding to the non-specific control is executed, the process corresponding to the non-specific control is not performed. Does not cause any problems.

Next, the check processing executed by calling the program of the subroutine in step S3908 will be described. In the check process, a process for collecting information on the game history, a process for deriving a game history management result, and a process for notifying the management result are executed. That is, the processing for collecting the information of the game history, the processing for deriving the management result of the game history, and the processing for notifying the management result are executed as the processing corresponding to the non-specific control.

Prior to the description of the check process, the contents of various areas 231 to 234 of the non-specific control work area 223 used for managing the game history will be described. FIG. 72 is an explanatory diagram for explaining various areas 231 to 234 of the work area 223 for non-specific control used for managing the game history.

The non-specific control work area 223 is provided with a normal counter area 231, an opening/closing execution mode counter area 232, and a high frequency support mode counter area 233. In each of these areas 231-233, general prize winning counters 231a, 232a, 233a, special electric prize winning counters 231b, 232b, 233b, first operation counters 231c, 232c, 233c, second operation counters 231d, 232d, 233d, and Out counters 231e, 232e, 233e are provided. The general payout counters 231a, 232a, 233a are counters for measuring the number of game balls entered into the general payout opening 31 from a predetermined measurement start timing. The special electric prize winning counters 231b, 232b, 233b are counters for measuring the number of game balls entered into the special electric prize winning device 32 from a predetermined measurement start timing. The first operation counters 231c, 232c, 233c are counters for measuring the number of game balls entering the first operation port 33 from a predetermined measurement start trigger. The second operation counters 231d, 232d, 233d are counters for measuring the number of game balls entering the second operation port 34 from a predetermined measurement start trigger. The out counters 231e, 232e, 233e are counters for measuring the number of game balls entering the out port 24a from a predetermined measurement start trigger.

Each of the counters 231a to 231e in the normal counter area 231 is a target ball entry portion 24a in a situation where the front door frame 14 is in a closed state and is neither the open/close execution mode nor the high frequency support mode. It is used to count the number of game balls that enter 31 to 34. Each of the counters 232a to 232e in the opening/closing execution mode counter area 232 enters the target ball-in portion 24a, 31 to 34 in the situation where the front door frame 14 is in the closed state and the opening/closing execution mode is in effect. It is used to count the number of game balls played. The counters 233a to 233e in the high-frequency support mode counter area 233 are the target ball-in portions 24a, 31 to 34 in the high-frequency support mode in which the front door frame 14 is closed. It is used to measure the number of game balls that enter the ball.

In addition, the situation where the front door frame 14 is in the open state is out of the measurement target because the game ball enters the ball entry portions 24a, 31 to 34 with the front door frame 14 open. This is because the number of entered balls in the case of being excluded is excluded from the measurement target. However, the present invention is not limited to this, and a configuration in which the front door frame 14 is in the open state may be a measurement target similarly to the situation in which the front door frame 14 is in the closed state.

The work area 223 for non-specific control is provided with a calculation result storage area 234 in addition to the normal counter area 231, the open/close execution mode counter area 232, and the high frequency support mode counter area 233. The calculation result storage area 234 is an area for storing information on the management result of the game history calculated by using the normal counter area 231, the opening/closing execution mode counter area 232, and the high frequency support mode counter area 233. .. The information on the management result of the game history stored in the calculation result storage area 234 is stored and held until the information on the management result of the game history is newly calculated to overwrite the newly calculated information.

FIG. 73 is a flowchart showing the check processing executed by calling the program of the subroutine in step S3908. The processes of steps S4001 to S4008 in the check process, including the process of the subroutine, are executed by the main CPU 63 using the non-specific control program and the non-specific control data. When executing the processing of the subroutine, the information on the return address after the execution of the processing of the subroutine is written in the storage area corresponding to the current value of the stack pointer of the main CPU 63 in the stack area 224 for non-specific control. At the same time, the value of the stack pointer is updated to the address information of the storage area to be stored in the next order. When the processing of the subroutine is completed, the information of the return address is read from the storage area corresponding to the value of the current stack pointer of the main CPU 63, which corresponds to the value of the previous order, and the information of the return address is corresponded to. While returning to the program, the value of the stack pointer is updated to the information of the address of the storage area from which the information of the return address is read.

In the check process, when the front door frame 14 is in the open state (step S4001: YES), a normal ball entry management process (step S4004), a ball entry management process in the opening/closing execution mode (step S4005), and a high frequency. The result calculation process (step S4007) and the display process (step S4008), which will be described later, are executed without executing any of the incoming ball management process (step S4006) in the support mode. Since the game area PA is formed by the space defined by the back surface of the window panel 52 provided on the front door frame 14 and the front surface of the game board 24, the front door frame 14 is opened. Even if the game area PA is opened toward the front and the game ball is shot toward the game area PA in that situation, the game ball cannot normally flow down the game area PA. Further, when the game balls enter the ball entrance portions 24a, 31 to 34 in a state where the front door frame 14 is in the open state, the game hall manager may perform maintenance or trouble elimination. This is a case where the front door frame 14 is opened and game balls enter due to care. Since the entry of such a game ball is not the entry of the game ball in the execution state of the regular game, it is not necessary to manage the entry of such a game ball. Therefore, in the check processing, if the front door frame 14 is in the open state as described above, none of the processing of steps S4004 to S4006 is executed.

When the front door frame 14 is in the closed state and is neither in the open/close execution mode nor the high frequency support mode (step S4001 to step S4003: NO), a normal entrance management process is executed (step S4004). If the front door frame 14 is in the closed state and is in the open/close execution mode (step S4001: NO, step S4002: YES), the entrance management process in the open/close execution mode is executed (step S4005). If the front door frame 14 is in the closed state and is in the high frequency support mode (step S4001: NO, step S4003: YES), the entrance management process in the high frequency support mode is executed (step S4006).

FIG. 74 is a flowchart showing the normal entrance management process in step S4004.

When it is determined that one gaming ball is detected by the first winning hole detection sensor 42a (step S4101: YES), that is, the signal received from the first winning hole detection sensor 42a is switched from LOW level to HI level. When it is confirmed that it has been changed, when it is determined that one gaming ball is detected by the second winning hole detection sensor 43a (step S4103: YES), that is, the signal received from the second winning hole detection sensor 43a. Is confirmed to have switched from the LOW level to the HI level, or when it is determined that one gaming ball has been detected by the third winning hole detection sensor 44a (step S4105: YES), that is, the third winning opening. When it is confirmed that the signal received from the detection sensor 44a is switched from the LOW level to the HI level, the value of the normal general winning award counter 231a is incremented by 1 (step S4102, step S4104, step S4106).

In the case of the entrance management process in the open/close execution mode, the value of the general winning counter 232a for the open/close execution mode is incremented by 1 as the process corresponding to steps S4102, S4104 and S4106, and the winning in the high frequency support mode is performed. In the case of ball management processing, the value of the general winning counter 233a for the high frequency support mode is incremented by 1 as the processing corresponding to steps S4102, S4104 and S4106. In addition, in the ball detection processing (step S3709) of the timer interrupt processing (FIG. 69) executed as the processing corresponding to the specific control, the detection results of the first to third winning hole detection sensors 42a to 44a are monitored, and When it is determined that one of the game balls is detected by any of the first to third winning opening detection sensors 42a to 44a, a process for paying out the number of gaming balls corresponding to the general winning opening 31 To execute.

When it is determined that one game ball is detected by the special electric detection sensor 45a (step S4107: YES), that is, it is confirmed that the signal received from the special electric detection sensor 45a is switched from the LOW level to the HI level. In this case, the value of the special electric prize winning counter 231b for normal is incremented by 1 (step S4108).

In the case of the entrance management process in the high frequency support mode, the value of the special electricity prize counter 232b for the opening/closing execution mode is incremented by 1 as the process corresponding to step S4108 in the case of the entrance management process in the open/close execution mode. As the process corresponding to step S4108, 1 is added to the value of the special electric prize winning counter 233b for the high frequency support mode. Further, the detection result of the special electric power detection sensor 45a is also monitored in the incoming ball detection processing (step S3709) of the timer interrupt processing (FIG. 69) executed as the processing corresponding to the specific control, and one electric power detection sensor 45a detects one electric power. When it is determined that a game ball has been detected, a process for causing the number of game balls corresponding to the special electric prize winning device 32 to be paid out is executed, and a process for specifying the timing for ending the round game is executed.

When it is determined that one game ball is detected by the first working opening detection sensor 46a (step S4109: YES), that is, the signal received from the first working opening detection sensor 46a is switched from the LOW level to the HI level. When it is confirmed that the value has been changed, the value of the normal first operation counter 231c is incremented by 1 (step S4110).

In the case of the entrance management process in the open/close execution mode, as the process corresponding to step S4110, the value of the first operation counter 232c for the opening/closing execution mode is incremented by 1, and the entrance management process in the high frequency support mode may be performed. For example, as the processing corresponding to step S4110, the value of the first operation counter 233c for the high frequency support mode is incremented by 1. Further, the detection result of the first working opening detection sensor 46a is also monitored in the entrance detection processing (step S3709) of the timer interrupt processing (FIG. 69) executed as the processing corresponding to the specific control, and the first working opening detection sensor is detected. When it is determined that one game ball is detected at 46a, a process for paying out the number of game balls corresponding to the first operating port 33 is executed and the pending information for special figures is acquired. Execute the process to identify the trigger.

When it is determined that the one game ball is detected by the second working opening detection sensor 47a (step S4111: YES), that is, the signal received from the second working opening detection sensor 47a is switched from the LOW level to the HI level. If it is confirmed that the value has been changed, the value of the normal second operation counter 231d is incremented by 1 (step S4112).

In the case of the entrance management process in the open/close execution mode, the value of the second operation counter 232d for the opening/closing execution mode is incremented by 1 as the process corresponding to step S4112, and the entrance management process is in the high frequency support mode. For example, as the process corresponding to step S4112, the value of the second operation counter 233d for the high frequency support mode is incremented by 1. Further, the detection result of the second working opening detection sensor 47a is also monitored in the entrance detection processing (step S3709) of the timer interruption processing (FIG. 69) executed as the processing corresponding to the specific control, and the second working opening detection sensor is detected. When it is determined that one game ball is detected at 47a, a process for causing the number of game balls corresponding to the second operation port 34 to be paid out is executed, and the pending information for special figures is acquired. Execute the process to identify the trigger.

When it is determined that one gaming ball is detected by the out-mouth detecting sensor 48a (step S4113: YES), that is, the signal received from the out-mouth detecting sensor 48a is switched from the LOW level to the HI level. If confirmed, the value of the normal out counter 231e is incremented by 1 (step S4114).

In the case of the entrance management process in the opening/closing execution mode, the value of the out counter 232e for the opening/closing execution mode is incremented by 1 as the process corresponding to step S4114. As the process corresponding to S4114, 1 is added to the value of the out counter 233e for the high frequency support mode. Further, in the entrance detection process (step S3709) of the timer interrupt process (FIG. 69) executed as the process corresponding to the specific control, the detection result of the outlet detection sensor 48a is not monitored.

By performing the processing of step S4004 to step S4006 as described above, the number of game balls entered into the general winning opening 31 is measured by using the general prize counters 231a, 232a, 233a, and the special prize winning device 32. The number of game balls entering the game ball is measured using the special electric prize winning counters 231b, 232b, 233b, and the number of game ball entering the first working port 33 is measured using the first working counters 231c, 232c, 233c. Is measured by using the second operation counters 231d, 232d, 233d, and the number of game balls entering the second operating port 34 is measured by using the second operation counters 231d, 232d, 233d. It is measured using 232e and 233e. As a result, the main CPU 63 can grasp the history of ball entry into each ball entry section 24a, 31 to 34. In addition, since the normal counter area 231, the open/close execution mode counter area 232, and the high-frequency support mode counter area 233 are separately provided, it is possible that neither the open-close execution mode nor the high-frequency support mode is present. It is possible for the main CPU 63 to grasp the entry history into each entry part 24a, 31 to 34 by distinguishing between the open/close execution mode and the high-frequency support mode.

Returning to the explanation of the check process (FIG. 73 ), if an affirmative determination is made in step S4001, the process of step S4004 is executed, the process of step S4005 is executed, or the process of step S4006 is executed, A result calculation process is executed in step S4007, and a display process is executed in step S4008.

FIG. 75 is a flowchart showing the result calculation process of step S4007.

First, it is determined whether or not "1" is set in the management start flag provided in the work area 223 for non-specific control (step S4201). The management start flag is a flag for the main CPU 63 to specify whether or not the game history collection for calculating the game history management result should be executed. In the present embodiment, when the supply of operating power to the pachinko machine 10 is started for the first time after the pachinko machine 10 is manufactured (that is, the supply of operating power to the MPU 62 is started), the game discharged from the game area PA. Until the total number of balls exceeds the number corresponding to the management start reference value, the total number of game balls discharged from the game area PA is not collected without collecting the game history for calculating the management result of the game history. When the number becomes greater than or equal to the management start reference value, the game history is collected to calculate the management result of the game history. At the shipping stage of the pachinko machine 10 or the like, the operation check of the pachinko machine 10 may be performed before shipping, in which case the game ball is cared for in each ball entry portion and the subsequent operation is checked. On the other hand, a game for calculating the management result of the game history until the total number of the game balls discharged from the game area PA after the start of the supply of the operating power to the pachinko machine 10 becomes the management start reference value or more. By not allowing the history to be collected, it is possible to prevent the result of entering the ball during the above operation check from being collected as the game history for calculating the management result of the game history. Become.

Here, when the supply of the operating power to the pachinko machine 10 is started for the first time after the pachinko machine 10 is manufactured (that is, the supply of the operating power to the MPU 62 is started), the value of the management start flag is “0”. Has become. In this case, the values of the counters 231a to 231e of the normal counter area 231, the values of the counters 232a to 232e of the open/close execution mode counter area 232, and the values of the counters 233a to 233e of the high-frequency support mode counter area 233. Is also "0". On the other hand, in a situation where the value of the management start flag is "1", the supply of operating power to the pachinko machine 10 is stopped, and then the operating power to the pachinko machine 10 is supplied in a situation where backup power is supplied to the main RAM 65. When the supply of No. is started, the value of the management start flag remains "1". In this case, the values of the counters 231a to 231e of the normal counter area 231, the values of the counters 232a to 232e of the open/close execution mode counter area 232, and the values of the counters 233a to 233e of the high frequency support mode counter area 233. Also, the state before the supply of the operating power to the pachinko machine 10 is stopped is maintained. With the above configuration, when the value of the management start flag is "0", the values of the counters 231a to 231e in the normal counter area 231 and the values of the counters 232a to 232e in the open/close execution mode counter area 232. The values of the counters 233a to 233e in the high-frequency support mode counter area 233 are also "0".

By the way, when the main RAM 65 clearing process is executed in step S105 or step S117 in the main process (FIG. 9), the target of the clearing process is the work area 221 for the specific control and the stack for the specific control. The area 222, the work area 223 for non-specific control and the stack area 224 for non-specific control are excluded from the target of the clearing process. As a result, the game hall manager cannot intentionally clear the work area 223 for non-specific control and the stack area 224 for non-specific control to "0".

Further, the main CPU 63 confirms whether or not an abnormality has occurred in the work area 223 for non-specific control and the stack area 224 for non-specific control in the timer interrupt processing (FIG. 69) described later, and the abnormality is generated. When it is confirmed, the work area 223 for non-specific control and the stack area 224 for non-specific control may be cleared to “0”. This makes it possible to initialize the work area 223 for non-specific control and the stack area 224 for non-specific control when an abnormality occurs. In addition, when an abnormality occurs in the work area 223 for non-specific control in the configuration, the work area 223 for non-specific control is cleared to "0" without clearing the stack area 224 for non-specific control to "0". However, when an abnormality occurs in the stack area 224 for non-specific control, the stack area 224 for non-specific control is cleared to "0" without clearing the work area 223 for non-specific control to "0". Good. Further, even if an abnormality occurs in the work area 223 for non-specific control and the stack area 224 for non-specific control, the calculation result storage area 234 may be excluded from the target of clearing "0".

When a negative determination is made in step S4201, the values of the counters 231a to 231e in the normal counter area 231, the values of the counters 232a to 232e in the open/close execution mode counter area 232, and the high frequency support mode counter area 233 are determined. The total number is calculated by summing all the values of the counters 233a to 233e (step S4202). Then, it is determined whether or not the calculated total number is greater than the management start reference value “300” (step S4203).

When an affirmative determination is made in step S4203, the management start flag of the work area 223 for non-specific control is set to "1" (step S4204). Also, all the counters 231a to 231e in the normal counter area 231, the counters 232a to 232e in the open/close execution mode counter area 232, and the counters 233a to 233e in the high frequency support mode counter area 233 are all cleared to "0". (Step S4205). Thereby, the total number of game balls discharged from the game area PA after the supply of the operating power to the pachinko machine 10 is started (that is, after the supply of the operating power to the MPU 62 is started) is the management start reference value. All the game history information collected until the number of games corresponding to the above is exceeded will be erased. Therefore, after the start of the supply of the operating power to the pachinko machine 10, until the total number of game balls discharged from the game area PA becomes equal to or more than the management start reference value, the collection of the game history for calculating the management result of the game history. It becomes possible not to execute.

If an affirmative decision is made in step S4201, the calculation processing of the total number is executed as in step S4202 (step S4206). That is, the values of the counters 231a to 231e in the normal counter area 231, the values of the counters 232a to 232e in the open/close execution mode counter area 232, and the values of the counters 233a to 233e in the high-frequency support mode counter area 233 are set as follows. The total number is calculated by summing all. Then, it is determined whether or not the calculated total number is equal to or greater than the calculation reference number “6000” (step S4207).

If an affirmative decision is made in step S4207, arithmetic processing of various parameters is executed (step S4208). Specifically, the values of the various counters 231a to 231e in the normal counter area 231 are set to K61 to K65, the values of the various counters 232a to 232e in the open/close execution mode counter area 232 are set to K71 to K75, and the high frequency support mode is used. When the values of the various counters 233a to 233e in the counter area 233 are set to K81 to K85, the following 61st to 68th parameters are calculated.
61st parameter: total payout number of game balls (“K61+K71+K81”דnumber of prize balls for winning in the general winning opening 31”+“K62+K72+K82”דnumber of prize balls for winning in the special electric winning device 32”+“K63+K73+K83 "×"Number of prize balls for winning in the first operating port 33"+"K64+K74+K84" x "Number of prize balls for winning in the second operating port 34")/Total number of game balls discharged from the game area PA ( Ratio of K61+K62+K63+K64+K65+K71+K72+K73+K74+K75+K81+K82+K83+K84+K85) ・The 62nd parameter: the total payout amount of the game balls in the normal time (K61דthe number of prize balls for winning the prize at the general prize hole 31”+K62דthe special prize winning device 32”). X "Number of prize balls for winning in the first operating port 33" + K64 x "Number of prize balls for winning in the second operating port 34") / Total number of game balls discharged from the game area PA in the normal time (K61 + K62 + K63 + K64 + K65) ) 63rd parameter: total payout number of game balls in the open/close execution mode (K71 x "number of prize balls for winning in the general prize hole 31" + K72 x "number of prize balls for winning in the special prize winning device 32") +K73 x "number of prize balls for winning in the first operating port 33" +K74 x "number of prize balls for winning in the second operating port 34")/total of game balls discharged from the game area PA in the opening/closing execution mode Ratio of the number (K71+K72+K73+K74+K75) ・The 64th parameter: the total payout number of game balls in the high frequency support mode (K81 x "the number of prize balls for winning in the general winning hole 31" + K82 x "for winning the special electric prize device 32") "Number of prize balls" + K83 x "Number of prize balls for winning in the first operating port 33" + K84 x "Number of prize balls for winning in the second operating port 34")/is discharged from the game area PA in the high-frequency support mode percentage - 65 parameters of the total number of playing balls (K81 + K82 + K83 + K84 + K85): percentage of the total number of general total ball entrance number of game balls to winning hole 31 (K61 + K71 + K81) / game region game ball discharged from PA (K61 + K62 + K63 + K64 + K65 + K71 + K72 + K73 + K74 + K75 + K81 + K82 + K83 + K84 + K85) -66th parameter: the total number of entered game balls into the first operating port 33 (K63 + K7 3+K83)/total number of game balls discharged from the game area PA (K61+K62+K63+K64+K65+K71+K72+K73+K74+K75+K81+K82+K83+K84+K85) 67th parameter: (“K62+K72+K82”דK62+K72+K82” to “K+ special prize winning device 64”) 2) Number of prize balls for winning in the operating port 34)/total number of payouts of game balls ("K61+K71+K81" x "Number of prize balls for winning in the general winning port 31" + "K62+K72+K82" x "Toward special prize winning device 32" Ratio of the number of prize balls for winning prize+K63+K73+K83×the number of prize balls for winning the first operating port 33+K64+K74+K84×the number of prize balls for winning the second operating port 34) Parameter: “K62+K72+K82”דnumber of prize balls for winning in special electric prize winning device 32”/total number of game balls paid out (“K61+K71+K81”דnumber of prize balls for winning in the general winning opening 31”+“K62+K72+K82”ד "Number of prize balls for winning the special electric prize winning device 32" + "K63 + K73 + K83" x "Number of prize balls for winning the first operating port 33" + "K64 + K74 + K84" x "Number of prize balls for winning the second operating port 34" After that, the 61st to 68th parameters calculated in step S4208 are overwritten in the calculation result storage area 234 (step S4209). In this case, the 61st to 68th parameters of the calculation result in the previous processing times, which are already stored in the calculation result storage area 234, are erased. Even when the supply of the operating power to the pachinko machine 10 is stopped, the backup power is supplied to the main RAM 65. Therefore, if the backup power is supplied to the pachinko machine 10, Even immediately after the start of the supply of the operating power, the calculation result storage area 234 stores the information of the 61st to 68th parameters calculated before the supply of the operating power to the pachinko machine 10 is stopped.

After that, all the counters 231a to 231e in the normal counter area 231, the counters 232a to 232e in the open/close execution mode counter area 232, and the counters 233a to 233e in the high frequency support mode counter area 233 are all cleared to "0". (Step S4210). As a result, when the 61st to 68th parameters are calculated, it becomes possible to temporarily erase the information of the game history at that time.

Immediately after the management start flag is set to "1", when the total number of game balls discharged from the game area PA is equal to or more than the value obtained by subtracting the management start reference value from the calculation reference number, steps S4208 to The processing of step S4210 may be executed, and thereafter, the processing of steps S4208 to S4210 may be executed when the total number of game balls discharged from the game area PA is equal to or larger than the calculation reference number.

FIG. 76 is a flowchart showing the display processing of step S4008 in the check processing (FIG. 73).

First, the value of the update timing counter provided in the work area 223 for non-specific control is decremented by 1 (step S4301). The update timing counter is a counter for the main CPU 63 to specify that the display content of the management result of the game history on the first to third notification display devices 69a to 69c is updated. The main CPU 63 notifies the calculation results of the 61st to 68th parameters by controlling the display of the first to third notification display devices 69a to 69c. In this case, the first notification display device 69a displays information corresponding to the type of parameter to be notified. Further, among the values obtained by multiplying the parameter to be notified by 100, the numeral corresponding to the tens digit is displayed on the second notification display device 69b, and the numeral corresponding to the ones digit is displayed for the third notification. It is displayed on the device 69c. Then, in the first to third notification display devices 69a to 69c, the displays corresponding to the calculation results of the 61st to 68th parameters are sequentially switched according to a predetermined order, and are the display objects in the final order. After the calculation result of the 68th parameter is displayed, the calculation result of the 61st parameter, which is the display target in the first order, is displayed. In this case, the period during which the calculation result of one parameter is continuously displayed is 10 seconds.

Here, the calculation cycle of the 61st to 68th parameters in the main CPU 63 is 60 minutes at the shortest. On the other hand, the number of the 61st to 68th parameters is 8, and the period during which the calculation result of one parameter is continuously displayed is 10 seconds. Therefore, the 61st to 68th parameters calculated by the main CPU 63 are displayed at least once on the first to third notification display devices 69a to 69c.

When the process of step S4301 is executed, the display contents of the first to third notification display devices 69a to 69c are updated by determining whether the value of the update timing counter after subtracting 1 is “0”. It is determined whether or not the timing has come (step S4302). When an affirmative determination is made in step S4302, the value of the display target counter provided in the work area 223 for non-specific control is incremented by 1 (step S4303). When the value of the display target counter after adding 1 exceeds the maximum value of "7" (step S4304: YES), the value of the display target counter is cleared to "0" (step S4305).

The display target counter is a counter for the main CPU 63 to specify the type of parameter to be displayed on the first to third notification display devices 69a to 69c. There is a one-to-one correspondence between the 61st to 68th parameters and the possible values of the display target counters of "0" to "7". For example, when the value of the display target counter is “0”, the 61st parameter, which is the first display target, becomes the display target of the first to third notification display devices 69a to 69c, and the value of the display target counter is “7”. In this case, the 68th parameter, which is the last display target, becomes the display target of the first to third notification display devices 69a to 69c.

If a negative determination is made in step S4304, or if the processing of step S4305 is executed, the first notification display device 69a is displayed so that information corresponding to the type of parameter corresponding to the value of the display target counter is displayed. It is controlled (step S4306). Further, the parameter corresponding to the value of the display target counter is read from the calculation result storage area 234, the read parameter is multiplied by 100, and the numeral corresponding to the tens digit is displayed on the second notification display device 69b. The number corresponding to the ones digit is displayed on the third notification display device 69c (step S4307).

Here, a display IC is provided corresponding to each of the first to third notification display devices 69a to 69c. In step S4306, the main CPU 63 outputs the display data to the display IC corresponding to the first notification display device 69a, and in step S4307 the main CPU 63 displays the display IC corresponding to the second notification display device 69b and the third notification. The display data is output to each of the display ICs corresponding to the display device 69c for display. These display ICs can store and hold display data when operating power is supplied, and display contents corresponding to the stored and held display data are continuously displayed on the corresponding notification display devices 69a to 69c. Display it. Then, by changing the display data by the main CPU 63, the display of the notification display devices 69a to 69c is changed to the display content corresponding to the changed display data. As a result, even after the management execution process (FIG. 71), which is the process corresponding to the non-specific control, is completed and the process corresponding to the specific control is returned to, the execution status of the process corresponding to the non-specific control is set. The display corresponding to the display data will be continued on the first to third notification display devices 69a to 69c.

After that, a value corresponding to 10 seconds is set as a value corresponding to the next update timing in the update timing counter of the work area 223 for non-specific control (step S4308).

When the supply of operating power to the main CPU 63 is started by executing the display processing as described above, the game history management result is displayed on the first to third notification display devices 69a to 69c. To be done. The management result of the game history is displayed regardless of whether the game is continued or not, and the main body of the gaming machine 12 is opened with respect to the outer frame 11 so that the main controller 60 is operated from the front of the pachinko machine 10. It is performed regardless of whether it is visible. In this way, the display control of the first to third notification display devices 69a to 69c is executed irrespective of the status of the game and the state of the pachinko machine 10, so that the first to third notification display device 69a. It is possible to simplify the processing configuration for controlling the display of ~69c.

According to this embodiment described in detail above, the following excellent effects are exhibited.

The main RAM 65 is provided with a work area 221 for specific control and a stack area 222 for specific control, a work area 223 for non-specific control and a stack area 224 for non-specific control. In the specific control work area 221 and the specific control stack area 222, a process corresponding to the specific control is executed by the main CPU 63 using the specific control program and the specific control data. While the information can be stored and the information can be read out, the main CPU 63 executes the process corresponding to the non-specific control using the non-specific control program and the non-specific control data. In this case, the information can be read but the information cannot be stored. Further, the work area 223 for non-specific control and the stack area 224 for non-specific control are capable of storing information and reading information when the processing corresponding to the non-specific control is executed by the main CPU 63. On the other hand, when the processing corresponding to the specific control is executed by the main CPU 63, the information can be read but the information cannot be stored. As a result, the work area 221 for specific control and the stack area 222 for specific control are treated as a dedicated storage area for the process corresponding to the specific control, and the work area 223 for non-specific control and the stack area for non-specific control are provided. It is possible to handle 224 as a dedicated storage area for processing corresponding to non-specific control. Therefore, the storage destination of information in the main RAM 65 can be clearly different between the process corresponding to the specific control and the process corresponding to the non-specific control. Therefore, when one of the processes corresponding to the specific control and the process corresponding to the non-specific control is executed, it is possible to prevent the information used in the other process from being erased.

The process corresponding to the specific control includes a process for controlling the progress of the game, and the process corresponding to the non-specific control includes a process for managing the game history. Then, as described above, the work area 221 for specific control and the stack area 222 for specific control are treated as a dedicated storage area for the processing corresponding to the specific control, and the work area 223 for non-specific control and the non-specific control Stack area 224 is treated as a dedicated storage area for processing corresponding to non-specific control. Thereby, when executing the process for controlling the progress of the game, information used in the process for managing the game history, for example, the normal counter area 231, the opening/closing execution mode counter area 232, the high frequency support mode It is possible to prevent the information stored in the use counter area 233 and the calculation result storage area 234 from being rewritten.

A normal counter area 231, an opening/closing execution mode counter area 232, a high frequency support mode counter area 233, and a calculation result storage area 234, which store information for managing the game history, are provided in the main RAM 65. This allows the main CPU 63 to complete the processing for managing the game history. Further, it is possible to prevent unauthorized access or unauthorized modification to the information on the game history and the information on various parameters calculated using the information on the game history.

When the process corresponding to the non-specific control is executed from the condition in which the process corresponding to the specific control is executed, or when the process corresponding to the non-specific control is executed, various types of main CPU 63 The information in the register is saved in the main RAM 65. Thus, when the process corresponding to the non-specific control is executed, it is possible to prevent the information stored in the various registers of the main CPU 63 from being rewritten when the process corresponding to the specific control is executed. Become. In addition, when the processing corresponding to the non-specific control is completed or after the processing is completed, the information saved in the main RAM 65 is restored to various registers of the main CPU 63. As a result, when the process corresponding to the non-specific control is completed, it is possible to execute the process corresponding to the specific control from the state of various registers of the main CPU 63 before the execution of the process corresponding to the non-specific control. Become.

When a situation in which a process corresponding to the non-specific control is executed from a situation in which the process corresponding to the specific control is executed, or when a process corresponding to the non-specific control is executed, various registers of the main CPU 63 Information of some of the registers is saved in the main RAM 65. This makes it possible to reduce the storage capacity necessary for saving the information in the register of the main CPU 63 in the main RAM 65.

When a situation in which a process corresponding to the non-specific control is executed from a situation in which the process corresponding to the specific control is executed, or when a process corresponding to the non-specific control is executed, various registers of the main CPU 63 Of the registers, the information of the register that is the storage target of the information in the process corresponding to the non-specific control is saved in the main RAM 65. As a result, when the processing corresponding to the non-specific control is completed, it is possible to restart the processing corresponding to the specific control from the state of the register of the main CPU 63 before the execution of the processing corresponding to the non-specific control. In the main RAM 65, it is possible to reduce the storage capacity necessary for saving the information in the register of the main CPU 63.

When the process corresponding to the non-specific control is started, the information in the flag register of the main CPU 63 is saved in the stack area 222 for the specific control in the process corresponding to the specific control, and the WA register, BC register of the main CPU 63, Each information of the DE register, the HL register, the IX register, and the IY register is saved in the work area 223 for non-specific control in the process corresponding to the non-specific control. As a result, it becomes possible to save at a timing suitable for each information stored in the various registers of the main CPU 63, and the processing for saving information corresponds to the processing corresponding to the specific control and the non-specific control. It becomes possible to execute distributed processing.

The flag register includes a carry flag, a zero flag, a P/V flag, a sine flag, a half carry flag, etc., and the information in the flag register changes depending on the execution result of an arithmetic instruction, a rotate instruction, an input/output instruction, and the like. In this case, the information in the flag register is saved in the stack area 222 for specific control in the processing corresponding to the specific control before the processing corresponding to the non-specific control is started. This makes it possible to save the information of the flag register in the state before the call of the subroutine corresponding to the non-specific control or the start of the subroutine and before the change in the stack area 222 for the specific control.

By saving the information of the WA register, BC register, DE register, HL register, IX register, and IY register in the work area 223 for non-specific control instead of saving it in the stack area 224 for non-specific control, It is possible to keep the capacity of the stack area 224 for specific control small. Further, when the stack area 224 for non-specific control is used, the writing order of information is read first from the later information. Therefore, if the reading order of information is deviated due to some noise or the like, it may occur. All subsequent read order information will be restored to a different register. The probability of occurrence of such an event increases as the amount of information saved in the stack area 224 for non-specific control increases. On the other hand, by saving the information in the register in the work area 223 for non-specific control, it is possible to prevent the above event from occurring even when there is a large amount of information to be saved. ..

The stack pointer of the main CPU 63 when the processing corresponding to the non-specific control is changed from the status where the processing corresponding to the specific control is executed to the status where the processing corresponding to the non-specific control is executed Information is fixed information, and the information of the stack pointer is not saved in the main RAM 65 at the start of the process corresponding to the non-specific control. As a result, it is not necessary to secure a capacity for saving the stack pointer information in the main RAM 65, so that the storage capacity of the main RAM 65 can be suppressed accordingly. Even if the stack pointer information is not saved in this way, when the situation corresponding to the non-specific control is changed from the situation corresponding to the non-specific control to the situation where the process corresponding to the non-specific control is executed. When the situation in which the corresponding process is executed, the information on the stack pointer of the main CPU 63 becomes fixed information, and thus the process corresponding to the non-specific control can be performed without saving the information on the stack pointer as described above. When finished, it is possible to return to the information of the stack pointer before the process corresponding to the non-specific control is started.

Although the information in the flag register of the main CPU 63 is saved in the main RAM 65 in the processing corresponding to the specific control when the processing corresponding to the non-specific control is executed, the present invention is not limited to this. Instead, the flag register information may be saved in the main RAM 65 in the process corresponding to the non-specific control. Further, although the configuration is such that after the processing corresponding to the non-specific control is completed, the information is returned to the flag register of the main CPU 63 in the processing corresponding to the specific control, but the present invention is not limited to this. The information may be returned to the flag register in a process corresponding to the non-specific control.

In addition, after the processing corresponding to the non-specific control is started for the information of the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63, the main processing is performed in the processing corresponding to the non-specific control. Although the configuration is such that the information is saved in the side RAM 65, the information in these registers may be saved in the main RAM 65 in the processing corresponding to the specific control. Further, when the process corresponding to the non-specific control is completed, the information is returned to each of the registers in the process corresponding to the non-specific control, but the present invention is not limited to this. The information may be returned to the register in the process corresponding to the specific control after the process corresponding to the non-specific control is completed.

<Sixteenth Embodiment>
In this embodiment, the processing configuration of the management processing is different from that of the fifteenth embodiment. Hereinafter, a configuration different from that of the fifteenth embodiment will be described. The description of the same configuration as the fifteenth embodiment is basically omitted.

FIG. 77 is a flowchart showing the management process executed by the main CPU 63 in this embodiment. The processes of steps S4401 to S4405 in the management process are executed by the main CPU 63 using the specific control program and the specific control data.

First, in order to prohibit the occurrence of the timer interrupt process (FIG. 69), interrupt prohibition is set (step S4401). This prevents the timer interrupt process (FIG. 69), which is a process corresponding to the specific control, from being interrupted and activated in the middle of a management execution process, which will be described later, which is a process corresponding to the non-specific control. Is possible.

After that, as "LD (_PSWBUF), PSW", the information of the flag register of the main CPU 63 is saved to the PSW buffer set in the work area 221 for specific control by a load instruction (step S4402). The flag register includes a carry flag, a zero flag, a P/V flag, a sine flag, a half carry flag, etc., and the information in the flag register changes depending on the execution result of an arithmetic instruction, a rotate instruction, an input/output instruction, and the like. By saving such flag register information before the program of the subroutine corresponding to the management execution process is started, the flag register in the state before being changed after the subroutine is called or the subroutine is started is saved. The information can be saved in the work area 221 for specific control.

After that, the management execution process is started by reading the program of the subroutine corresponding to the management execution process set in the non-specific control program (step S4403). In this case, the information for specifying the return address of the management process after the execution of the management execution process is written in the stack area 222 for specific control by the push command. Then, when the management execution processing is completed, the information for specifying the return address is read by the pop command, and the program for the management processing indicated by the return address is returned to.

After returning to the management processing program after the execution of the management execution processing, a load instruction as "LD PSW, (_PSWBUF)" is executed to save it in the PSW buffer in the work area 221 for specific control in step S4402. The information in the flag register is returned to the flag register of the main CPU 63 (step S4404). As a result, the information in the flag register of the main CPU 63 is restored to the information at the time when step S4402 was previously executed. That is, the information in the flag register of the main CPU 63 is restored to the information for executing the specific control.

After that, the interrupt permission is set to switch from the state in which the generation of the timer interrupt process (FIG. 69) is prohibited to the state in which it is permitted (step S4405). This enables a new execution of the timer interrupt process.

According to the above configuration, the information in the flag register of the main CPU 63 immediately before switching from the specific control to the non-specific control is saved in the specific control work area 221 instead of the specific control stack area 222. This makes it possible to save the information in the flag register while suppressing the capacity of the stack area 222 for specific control.

Although the PSW buffer in the work area 221 for specific control is secured as a dedicated area, it is not limited to this and may be a shared area in which other information can be written. That is, it is not necessary to save the information in the flag register of the main CPU 63 corresponding to the specific control in the situation where the management processing is not executed. It is also possible to use a shared area that is also used as a PSW buffer when executing arithmetic processing. In this case, the shared area is surely used to save the information in the flag register when the management process is executed. Therefore, as the information other than the information in the flag register, before the management process is executed. It is necessary that the unnecessary information is written in the shared area.

<17th Embodiment>
In this embodiment, the processing configuration of the management execution processing is different from that of the fifteenth embodiment. Hereinafter, a configuration different from that of the fifteenth embodiment will be described. The description of the same configuration as the fifteenth embodiment is basically omitted.

FIG. 78 is a flowchart showing the management execution process executed in the main CPU 63 in this embodiment. The processes of steps S4501 to S4515 in the management execution process are executed by the main CPU 63 using the non-specific control program and the non-specific control data.

First, as in step S3901 of the management execution process (FIG. 71) in the fifteenth embodiment, when the non-specific control is started in the stack pointer of the main CPU 63 by the load instruction as “LD SP, Y(u+2)”. Y(u+2) is set as the fixed address in step S4501.

After that, as "PUSH WA", a push instruction saves the information in the WA register of the main CPU 63 to the storage area corresponding to the information of the current stack pointer of the main CPU 63 in the stack area 224 for non-specific control (step S4502). In this case, in step S4501, the WA register information is saved in the storage area corresponding to the fixed address set in the stack pointer of the main CPU 63. Also, the information of the stack pointer of the main CPU 63 is updated to the information of the address of the storage area to be written in the next order.

After that, as "PUSH BC", the push instruction saves the information of the BC register of the main CPU 63 to the storage area corresponding to the information of the current stack pointer of the main CPU 63 in the stack area 224 for non-specific control (step S4503). Also, the information of the stack pointer of the main CPU 63 is updated to the information of the address of the storage area to be written in the next order.

After that, as "PUSH DE", the push instruction saves the information in the DE register of the main CPU 63 to the storage area corresponding to the information of the current stack pointer of the main CPU 63 in the stack area 224 for non-specific control (step S4504). Also, the information of the stack pointer of the main CPU 63 is updated to the information of the address of the storage area to be written in the next order.

Thereafter, as "PUSH HL", a push instruction saves the information in the HL register of the main CPU 63 to the storage area corresponding to the current stack pointer information of the main CPU 63 in the stack area 224 for non-specific control (step S4505). Also, the information of the stack pointer of the main CPU 63 is updated to the information of the address of the storage area to be written in the next order.

After that, as "PUSH IX", the push instruction saves the information in the IX register of the main CPU 63 to the storage area corresponding to the current stack pointer information of the main CPU 63 in the stack area 224 for non-specific control (step S4506). Also, the information of the stack pointer of the main CPU 63 is updated to the information of the address of the storage area to be written in the next order.

Then, as "PUSH IY", a push instruction saves the information in the IY register of the main CPU 63 to the storage area corresponding to the current stack pointer information of the main CPU 63 in the stack area 224 for non-specific control (step S4507). Also, the information of the stack pointer of the main CPU 63 is updated to the information of the address of the storage area to be written in the next order.

After performing the processes of steps S4502 to S4507, the check process is performed (step S4508). When the check process is executed, the program of the subroutine corresponding to the check process set in the non-specific control program is executed. At the time of executing the program of the subroutine, information for specifying the return address of the management execution process after the execution of the check process is provided by the push command with the current stack pointer of the main CPU 63 in the stack area 224 for non-specific control. Write to the storage area corresponding to the information. When the check process is completed, the pop instruction reads the information for identifying the return address, and the program returns to the management execution process program indicated by the return address. The content of the check process is the same as that of the fifteenth embodiment.

After that, as in step S3909 of the management execution process (FIG. 71) in the fifteenth embodiment, the stack pointer of the main CPU 63 returns to the specific control by the load instruction as “LD SP, Y(r+α)”. Y(r+α) is set as the fixed address in step S4509. The address of Y(r+α) is set as an address between Y(r+8) and Y(s) in the stack area 222 for specific control.

After that, as "POP IY", the information saved in the storage area corresponding to the information in the previous order with respect to the information of the current stack pointer of the main CPU 63 in the stack area 224 for non-specific control by the pop instruction is displayed. The IY register of the main CPU 63 is overwritten (step S4510). Also, the information of the stack pointer of the main CPU 63 is updated to the information of the address of the storage area to be written in the previous order.

After that, as "POP IX", the information saved in the storage area corresponding to the information in the previous order with respect to the information of the current stack pointer of the main CPU 63 in the stack area 224 for non-specific control by the pop instruction is displayed. The IX register of the main CPU 63 is overwritten (step S4511). Also, the information of the stack pointer of the main CPU 63 is updated to the information of the address of the storage area to be written in the previous order.

Thereafter, as "POP HL", the information saved in the storage area corresponding to the information in the previous order with respect to the information of the current stack pointer of the main CPU 63 in the stack area 224 for non-specific control by the pop instruction is displayed. The HL register of the main CPU 63 is overwritten (step S4512). Also, the information of the stack pointer of the main CPU 63 is updated to the information of the address of the storage area to be written in the previous order.

After that, as "POP DE", the information saved in the storage area corresponding to the information in the previous order with respect to the information of the current stack pointer of the main CPU 63 in the stack area 224 for non-specific control by the pop instruction is displayed. The DE register of the main CPU 63 is overwritten (step S4513). Also, the information of the stack pointer of the main CPU 63 is updated to the information of the address of the storage area to be written in the previous order.

After that, as the "POP BC", the information saved in the storage area corresponding to the information in the previous order with respect to the information of the current stack pointer of the main CPU 63 in the stack area 224 for non-specific control by the pop instruction is displayed. The BC register of the main CPU 63 is overwritten (step S4514). Also, the information of the stack pointer of the main CPU 63 is updated to the information of the address of the storage area to be written in the previous order.

After that, as "POP WA", the information saved in the storage area corresponding to the information in the previous order with respect to the information of the current stack pointer of the main CPU 63 in the stack area 224 for non-specific control by the pop instruction is displayed. The WA register of the main CPU 63 is overwritten (step S4515). Also, the information of the stack pointer of the main CPU 63 is updated to the information of the address of the storage area to be written in the previous order.

By executing the processing of step S4510 to step S4515, processing corresponding to non-specific control is started for each information of the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63. It is possible to restore the information corresponding to the specific control immediately before.

In addition to the flag register, various registers of the main CPU 63 include various general-purpose registers, auxiliary registers, and index registers. In this case, in steps S4502 to S4507, information about each of the general-purpose registers, auxiliary registers, and index registers, which are some of the WA register, BC register, DE register, HL register, IX register, and IY register. Are saved in the stack area 224 for non-specific control. The WA register, BC register, DE register, HL register, IX register, and IY register are registers used in the check process (step S4508) corresponding to the non-specific control. By saving the information set in such registers in the stack area 224 for non-specific control before executing the check process (step S4508), the information in these registers used in the specific control is controlled by non-specific control. It is possible to evacuate before the start of. Therefore, even if these registers are overwritten during the non-specific control, the information saved in the stack area 224 for the non-specific control is restored to these registers when the non-specific control is finished, so that the states of these registers can be restored. Can be returned to the state corresponding to the specific control before the non-specific control is executed.

Also, instead of saving all the information of various general-purpose registers, auxiliary registers, and index registers in the stack area 224 for non-specific control, the WA to be used in the check processing corresponding to the non-specific control is used. Register information is saved in the stack area 224 for non-specific control by selectively saving information in the register, BC register, DE register, HL register, IX register, and IY register to the stack area 224 for non-specific control. Therefore, it becomes possible to suppress the capacity to be secured. Therefore, it is possible to save the information in the register as described above while securing a large capacity of the stack area 224 for non-specific control that can be used in the check processing.

<Eighteenth embodiment>
In this embodiment, the processing configuration of the management execution processing is different from that of the fifteenth embodiment. Hereinafter, a configuration different from that of the fifteenth embodiment will be described. The description of the same configuration as the fifteenth embodiment is basically omitted.

FIG. 79 is a flowchart showing the management execution process in this embodiment executed by the main CPU 63. The processes of steps S4601 to S4605 in the management execution process are executed by the main CPU 63 using the non-specific control program and the non-specific control data.

First, as in step S3901 of the management execution process (FIG. 71) in the fifteenth embodiment, when the non-specific control is started in the stack pointer of the main CPU 63 by the load instruction as “LD SP, Y(u+2)”. Y(u+2) is set as the fixed address in (step S4601).

After that, as “LD (_ALLBUF), ALL”, the information of all the registers of the main CPU 63 is saved in the ALL buffer set in the work area 223 for non-specific control by a load instruction (step S4602). As a result, not only the WA register, the BC register, the DE register, the HL register, the IX register, and the IY register that are used in the check process that is the process corresponding to the non-specific control, but also all other registers are included. The register information is collectively saved in the ALL buffer of the non-specific control work area 223. By thus saving all the registers of the main CPU 63 in the work area 223 for non-specific control, there is no need to selectively save the information in the registers of the main CPU 63.

Here, the registers to be saved include a flag register. The information of the flag register is saved in the stack area 222 for specific control in step S3802 of the management process (FIG. 70), but the information of the flag register is saved in the work area 223 for non-specific control in step S4602. To be done. This eliminates the need to selectively save the information in the register of the main CPU 63 including the information in the flag register. Further, even if the information in the flag register is duplicated and saved as described above, after the management execution processing is completed, in step S3804 of the management processing (FIG. 70), the special control stack area 222 is removed from the main CPU 63. Since the information is returned to the flag register of the above, when returning to the process corresponding to the specific control, the information of the flag register of the main CPU 63 can be returned to the state immediately before the execution of the management execution process. Becomes

After that, a check process is executed (step S4603). When the check process is executed, the program of the subroutine corresponding to the check process set in the non-specific control program is executed. At the time of executing the program of the subroutine, information for specifying the return address of the management execution process after the execution of the check process is provided by the push command with the current stack pointer of the main CPU 63 in the stack area 224 for non-specific control. Write to the storage area corresponding to the information. When the check process is completed, the pop instruction reads the information for identifying the return address, and the program returns to the management execution process program indicated by the return address. The content of the check process is the same as that of the fifteenth embodiment.

After that, as in step S3909 of the management execution process (FIG. 71) in the fifteenth embodiment, the stack pointer of the main CPU 63 returns to the specific control by the load instruction as “LD SP, Y(r+α)”. Y(r+α) is set as the fixed address in (step S4604). The address of Y(r+α) is set as an address between Y(r+8) and Y(s) in the stack area 222 for specific control.

After that, as "LD ALL, (_ALLBUF)", the information saved in the ALL buffer of the work area 223 for non-specific control is overwritten in the register corresponding to each of the main CPUs 63 by the load instruction (step S4605). This makes it possible to restore each piece of information in all the registers of the main CPU 63 to the information corresponding to the specific control immediately before the processing corresponding to the non-specific control is started.

According to the above configuration, the information in the register of the main CPU 63 is not saved in the stack area 224 for non-specific control, but is saved in the work area 223 for non-specific control. It is possible to keep the capacity of 224 small. Further, when the stack area 224 for non-specific control is used, the writing order of information is read first from the later information. Therefore, if the reading order of information is deviated due to some noise or the like, it may occur. All subsequent read order information will be restored to a different register. The probability of occurrence of such an event increases as the amount of information saved in the stack area 224 for non-specific control increases. On the other hand, by saving the information in the register in the work area 223 for non-specific control, it is possible to prevent the above event from occurring even when there is a large amount of information to be saved. ..

Further, when the information of the register of the main CPU 63 is saved in the work area 223 for non-specific control, the WA register, BC register, DE register, and HL register used in the check process that is the process corresponding to the non-specific control. , IX register and IY register, and information of all registers including other registers are collectively saved in the ALL buffer of the work area 223 for non-specific control. By thus saving all the registers of the main CPU 63 in the work area 223 for non-specific control, there is no need to selectively save the information in the registers of the main CPU 63.

Although the information of all the registers of the main CPU 63 is saved in the main RAM 65 in the processing corresponding to the non-specific control after the processing corresponding to the non-specific control is started, the present invention is not limited to this. Instead, the information of all the registers may be saved in the main RAM 65 in the process corresponding to the specific control. Further, when the processing corresponding to the non-specific control ends, the information is returned to all the registers in the processing corresponding to the non-specific control, but the present invention is not limited to this. The information may be restored in the process corresponding to the specific control after the process corresponding to the non-specific control is completed.

<19th Embodiment>
In this embodiment, the processing configuration of the management execution processing is different from that of the fifteenth embodiment. Hereinafter, a configuration different from that of the fifteenth embodiment will be described. The description of the same configuration as the fifteenth embodiment is basically omitted.

FIG. 80 is a flowchart showing the management execution process in this embodiment executed by the main CPU 63. The processes of steps S4701 to S4706 in the management execution process are executed by the main CPU 63 using the non-specific control program and the non-specific control data.

First, as "LD (_SPBUF), SP", the load instruction saves the information of the stack pointer of the main CPU 63 to the SP buffer set in the work area 223 for non-specific control (step S4701). As a result, the information of the stack pointer corresponding to the specific control immediately before the process corresponding to the non-specific control is started is saved in the work area 223 for the non-specific control.

After that, as in step S3901 of the management execution process (FIG. 71) in the fifteenth embodiment, when the non-specific control is started in the stack pointer of the main CPU 63 by the load instruction as “LD SP, Y(u+2)”. Y(u+2) is set as the fixed address in (step S4702).

After that, as a “PUSH ALL”, a push command is executed to transfer the information of all the registers of the main CPU 63 from the storage area corresponding to the current stack pointer information of the main CPU 63 in the stack area 224 for non-specific control and the storage area. It is saved in continuous storage areas (step S4703). In this case, since the information of all the registers of the main CPU 63 cannot be stored in one storage area in the non-specific control stack area 224, the current state of the main CPU 63 in the non-specific control stack area 224 is as described above. The storage area corresponding to the information of the stack pointer and the storage area continuous from the storage area are set as the save destination of the information of the register. Further, the information of the stack pointer of the main CPU 63 is updated to the information of the address of the storage area to be written in the next order with respect to the storage area in which the last information is stored when the information of all the registers is saved.

After that, a check process is executed (step S4704). When the check process is executed, the program of the subroutine corresponding to the check process set in the non-specific control program is executed. At the time of executing the program of the subroutine, information for specifying the return address of the management execution process after the execution of the check process is provided by the push command with the current stack pointer of the main CPU 63 in the stack area 224 for non-specific control. Write to the storage area corresponding to the information. When the check process is completed, the pop instruction reads the information for identifying the return address, and the program returns to the management execution process program indicated by the return address. The content of the check process is the same as that of the fifteenth embodiment.

After that, as "POP ALL", the information saved in the storage area corresponding to the information of the current stack pointer of the main CPU 63 in the stack area 224 for non-specific control and the storage area continuous from the storage area by the pop instruction. Are overwritten in the registers corresponding to the respective main CPUs 63 (step S4705). This makes it possible to restore the information of all the registers of the main CPU 63 to the information corresponding to the specific control immediately before the processing corresponding to the non-specific control is started.

After that, the information saved in the SP buffer of the work area 223 for non-specific control is overwritten on the stack pointer of the main CPU 63 by the load instruction as "LD SP, (_SPBUF)" (step S4706). As a result, the information of the stack pointer of the main CPU 63 is restored to the information corresponding to the specific control immediately before the processing corresponding to the non-specific control is started.

According to the above configuration, when the information in the register of the main CPU 63 is saved in the stack area 224 for non-specific control, the WA register, the BC register, and the DE used in the check process corresponding to the non-specific control are used. Not only the registers, the HL register, the IX register, and the IY register, but also the other registers, the information of all the registers is collectively saved in the stack area 224 for non-specific control. By thus saving all the registers of the main CPU 63 in the stack area 224 for non-specific control, it is not necessary to selectively save the information of the registers of the main CPU 63.

The information of the stack pointer corresponding to the specific control immediately before the process corresponding to the non-specific control is started is saved in the work area 223 for the non-specific control. Thereby, even if the information of the stack pointer corresponding to the specific control immediately before the process corresponding to the non-specific control is changed, the process corresponding to the non-specific control ends and the specific control is performed. When returning to the corresponding process, the information of the stack pointer of the main CPU 63 can be returned to the information corresponding to the specific control immediately before the process corresponding to the non-specific control is started.

Although the information of all the registers of the main CPU 63 is saved in the main RAM 65 in the processing corresponding to the non-specific control after the processing corresponding to the non-specific control is started, the present invention is not limited to this. Instead, the information of all the registers may be saved in the main RAM 65 in the process corresponding to the specific control. Further, when the processing corresponding to the non-specific control ends, the information is returned to all the registers in the processing corresponding to the non-specific control, but the present invention is not limited to this. The information may be restored in the process corresponding to the specific control after the process corresponding to the non-specific control is completed.

<Twentieth Embodiment>
In this embodiment, the processing configurations of the management process and the management execution process are different from those of the fifteenth embodiment. Hereinafter, a configuration different from that of the fifteenth embodiment will be described. The description of the same configuration as the fifteenth embodiment is basically omitted.

FIG. 81 is a flowchart showing the management processing executed in the main CPU 63 in this embodiment. The processes of steps S4801 to S4811 in the management process are executed by the main CPU 63 using the specific control program and the specific control data.

First, in order to prohibit the occurrence of the timer interrupt process (FIG. 69), interrupt prohibition is set (step S4801). This prevents the timer interrupt process (FIG. 69), which is a process corresponding to the specific control, from being interrupted and activated in the middle of a management execution process, which will be described later, which is a process corresponding to the non-specific control. Is possible.

After that, as "PUSH PSW", a push instruction saves the information in the flag register of the main CPU 63 to the stack area 222 for specific control (step S4802). The flag register includes a carry flag, a zero flag, a P/V flag, a sine flag, a half carry flag, etc., and the information in the flag register changes depending on the execution result of an arithmetic instruction, a rotate instruction, an input/output instruction, and the like. By saving such flag register information before the program of the subroutine corresponding to the management execution process is started, the flag register in the state before being changed after the subroutine is called or the subroutine is started is saved. Information can be saved in the stack area 222 for specific control.

After that, as "LD WA, 0", the WA register of the main CPU 63 is cleared to "0" by a load instruction (step S4803). Further, as "LD BC,0", the BC register of the main CPU 63 is cleared to "0" by a load instruction (step S4804). Also, as "LD DE,0", the DE register of the main CPU 63 is cleared to "0" by a load instruction (step S4805). Also, as "LD HL,0", the HL register of the main CPU 63 is cleared to "0" by a load instruction (step S4806). Also, as "LD IX,0", the IX register of the main CPU 63 is cleared to "0" by a load instruction (step S4807). Also, as "LD IY,0", the IY register of the main CPU 63 is cleared to "0" by a load instruction (step S4808).

In addition to the flag register, various registers of the main CPU 63 include various general-purpose registers, auxiliary registers, and index registers. In this case, in steps S4803 to S4808, the WA register, the BC register, the DE register, the HL register, the IX register, and the IY register, which are some of the various general-purpose registers, auxiliary registers, and index registers, are set. Clear "0". The WA register, BC register, DE register, HL register, IX register, and IY register are registers used in the check process (step S4902) corresponding to the non-specific control. Before the processing corresponding to the non-specific control is started, the states of these registers are cleared by clearing "0" to the management execution processing (step S4809) which is the processing corresponding to the non-specific control. In addition, the state immediately after the supply of the operating power to the main CPU 63 is started can be achieved.

In addition, each information of the WA register, BC register, DE register, HL register, IX register, and IY register before the process corresponding to the non-specific control starts after the process corresponding to the non-specific control ends. This is unnecessary information in the process corresponding to the specific control. Therefore, even if the information in these registers is cleared to "0" without being saved, no problem occurs in the processing corresponding to the specific control that is restored after the processing corresponding to the non-specific control ends.

After executing the processes of steps S4803 to S4808, the management execution process is started by reading the program of the subroutine corresponding to the management execution process set in the non-specific control program (step S4809). In this case, the information for specifying the return address of the management process after the execution of the management execution process is written in the stack area 222 for specific control by the push command. Then, when the management execution processing is completed, the information for specifying the return address is read by the pop command, and the program for the management processing indicated by the return address is returned to.

When returning to the management processing program after execution of the management execution processing, the flag register information saved in the stack area 222 for specific control in step S4802 by the pop command as “POP PSW” is used as the main CPU 63. It returns to the flag register (step S4810). As a result, the information in the flag register of the main CPU 63 is returned to the information at the time when step S4802 was previously executed. That is, the information in the flag register of the main CPU 63 is restored to the information for executing the specific control.

Thereafter, in order to switch from the state in which the generation of the timer interrupt processing (FIG. 69) is prohibited to the state in which the timer interrupt processing is permitted, the interrupt permission is set (step S4811). This enables a new execution of the timer interrupt process.

FIG. 82 is a flowchart showing the management execution process executed by the main CPU 63 in this embodiment. The processes of steps S4901 to S4909 in the management execution process are executed by the main CPU 63 using the non-specific control program and the non-specific control data.

First, as in step S3901 of the management execution process (FIG. 71) in the fifteenth embodiment, “LD SP,Y(u+2)” is set to the stack pointer of the main CPU 63 by the load instruction at the start of non-specific control. Y(u+2) is set as the fixed address (step S4901).

After that, a check process is executed (step S4902). When the check process is executed, the subroutine program corresponding to the check process set in the non-specific control program is executed. However, when executing the subroutine program, the management after the check process is executed. Information for specifying the return address of the execution process is written in the stack area 224 for non-specific control by the push command. When the check processing is completed, the pop instruction reads the information for specifying the return address, and the program returns to the management execution processing program indicated by the return address. The content of the check process is the same as that of the fifteenth embodiment.

After that, as "LD WA, 0", the WA register of the main CPU 63 is cleared to "0" by a load instruction (step S4903). Also, as "LD BC,0", the BC register of the main CPU 63 is cleared to "0" by a load instruction (step S4904). Also, as "LD DE, 0", the DE register of the main CPU 63 is cleared to "0" by a load instruction (step S4905). Also, as "LD HL,0", the HL register of the main CPU 63 is cleared to "0" by a load instruction (step S4906). Further, as "LD IX,0", the IX register of the main CPU 63 is cleared to "0" by a load instruction (step S4907). Also, as "LD IY,0", the IY register of the main CPU 63 is cleared to "0" by a load instruction (step S4908).

The WA register, BC register, DE register, HL register, IX register, and IY register are registers used in the check process (step S4902) corresponding to the non-specific control as described above. By clearing such registers to "0" prior to the return from the process corresponding to the non-specific control to the process corresponding to the specific control, the states of these registers can be The state immediately after the supply of the operating power to the side CPU 63 is started can be achieved.

Further, the information of the WA register, BC register, DE register, HL register, IX register, and IY register before the process corresponding to the specific control is not specified after the process corresponding to the specific control is completed. This is unnecessary information in the processing corresponding to the control. Therefore, even if the information in these registers is cleared to "0" without being saved, no problem occurs in the processing corresponding to the non-specific control that is restored after the processing corresponding to the specific control is completed.

After that, as in step S3909 of the management execution process (FIG. 71) in the fifteenth embodiment, the stack pointer of the main CPU 63 returns to the specific control by the load instruction as “LD SP, Y(r+α)”. Y(r+α) is set as the fixed address in step S4909. The address of Y(r+α) is set as an address between Y(r+8) and Y(s) in the stack area 222 for specific control.

According to the above configuration, when the process corresponding to the non-specific control is started from the situation where the process corresponding to the specific control is being executed, the WA register, BC register, DE register, HL register, IX register of the main CPU 63 And the IY register are cleared to "0". As a result, it is not necessary to save the information of each register in the main RAM 65. Therefore, there is no need to secure a capacity for saving each of these pieces of information.

Also, when returning to the process corresponding to the specific control from the situation where the process corresponding to the non-specific control is executed, the WA register, BC register, DE register, HL register, IX register and IY register of the main CPU 63 are set. The configuration is such that "0" is cleared. As a result, when returning to the process corresponding to the specific control, it becomes possible to return the state of each of these registers to the state immediately before the start of the process corresponding to the non-specific control.

The state where each of the registers is cleared to “0” is the state when the supply of operating power to the main CPU 63 is started. This makes it possible to simplify the processing configuration for setting each of the registers to a predetermined state when starting the process corresponding to the non-specific control and when returning to the process corresponding to the specific control. ..

When starting the process corresponding to the non-specific control and returning to the process corresponding to the specific control, the registers for which the “0” is cleared are some of the various registers of the main CPU 63. This makes it possible to reduce the processing load for setting each of the registers to a predetermined state when starting the process corresponding to the non-specific control and returning to the process corresponding to the specific control.

In a configuration in which the WA register, the BC register, the DE register, the HL register, the IX register, and the IY register are cleared to “0” when starting the process corresponding to the non-specific control and returning to the process corresponding to the specific control, Registers other than "0" are not cleared. This makes it possible to prevent the information required in the process corresponding to the specific control from being erased at the start of the process corresponding to the non-specific control.

Information of registers other than the WA register, the BC register, the DE register, the HL register, the IX register, and the IY register is not saved in the main RAM 65 at the start of the process corresponding to the non-specific control. As a result, there is no need to secure an area for saving the information in the main RAM 65.

The information of the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63 before the processing corresponding to the non-specific control starts after the processing corresponding to the non-specific control ends. This information is not used in the process corresponding to the specific control. As a result, even if the above-mentioned registers are cleared to “0” when the process corresponding to the non-specific control is started, the specific control is performed after the process corresponding to the non-specific control is completed. It is possible to prevent the processing from being affected.

Note that instead of the configuration of clearing the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63 to "0" in steps S4803 to S4808 in the management process (FIG. 81), The register may be initialized. That is, when the supply of the operating power to the main CPU 63 is started, the information of each register of the main CPU 63 is set to the initial state after being cleared to “0” once. In steps S4803 to S4808, each register may be set so as to be in this initial state. In this case, in each of the steps S4903 to S4908, the setting of each register is performed so as to be in the initial state, so that the state of each register is not specified when returning to the process corresponding to the specific control. It is possible to restore the state immediately before the processing corresponding to the control is started.

Further, in steps S4803 to S4808 in the management process (FIG. 81), the WA register, the BC register, the DE register, the HL register, the IX register, and the IY register of the main CPU 63 are replaced with a configuration in which they are cleared to “0”. The configuration may be such that "1" is set in all the registers. In this case, in step S4903 to step S4908 also, by setting "1" in all of the above registers, when returning to the process corresponding to the specific control, the state of each register is processed corresponding to the non-specific control. It is possible to return to the state immediately before the start of.

Further, when the processing corresponding to the non-specific control is executed, the information of the flag register of the main CPU 63 is saved in the main RAM 65 in the processing corresponding to the specific control, but the present invention is not limited to this. Instead, the flag register information may be saved in the main RAM 65 in the process corresponding to the non-specific control. Further, although the configuration is such that after the processing corresponding to the non-specific control is completed, the information is returned to the flag register of the main CPU 63 in the processing corresponding to the specific control, but the present invention is not limited to this. The information may be returned to the flag register in a process corresponding to the non-specific control.

Further, the process of clearing the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63 to "0" corresponds to the specific control before the process corresponding to the non-specific control is started. However, the configuration is not limited to this, and the process of clearing these registers to "0" may be performed by the process corresponding to the non-specific control. Further, when the processing corresponding to the non-specific control ends, the processing for clearing each register to “0” is performed in the processing corresponding to the non-specific control, but the present invention is not limited to this. The processing of clearing each of the registers to “0” may be performed in the processing corresponding to the specific control after the processing corresponding to the non-specific control is completed.

In the management process (FIG. 81), the process of “PUSH PSW” in step S4802 is executed before setting “0” to each register in steps S4803 to S4808. However, instead of this, The processing of "PUSH PSW" in step S4802 is executed after "0" is set in each register in steps S4803 to S4808 and before the program of the subroutine corresponding to the management execution processing is read in step S4809. It may be configured to be. This makes it possible to save the information in the flag register, which has been changed by the load instruction in steps S4803 to S4808, in the stack area 222 for specific control.

<Twenty-first embodiment>
In this embodiment, the configuration for collecting information on the game history is different from that of the fifteenth embodiment. Hereinafter, a configuration different from that of the fifteenth embodiment will be described. The description of the same configuration as the fifteenth embodiment is basically omitted.

FIG. 83 is an explanatory diagram for explaining the electrical configuration of this embodiment.

The MPU 62 is provided with a main CPU 63, a main ROM 64, and a main RAM 65 as in the fifteenth embodiment. Further, unlike the fifteenth embodiment, the MPU 62 is electrically connected with the management RAM 241. That is, the management RAM 241 is provided separately from the main RAM 65 built in the MPU 62, and the management RAM 241 is externally attached to the MPU 62.

The main RAM 65 is provided with a work area 221 for specific control, a stack area 222 for specific control, a work area 223 for non-specific control, and a stack area 224 for non-specific control as in the fifteenth embodiment. ing. Therefore, when the main CPU 63 executes the process corresponding to the specific control by using the specific control program and the specific control data in the main ROM 64, the specific control work area 221 in the main RAM 65 and When the stack area 222 for specific control is used and the main CPU 63 uses the program for non-specific control and the data for non-specific control in the main ROM 64 to execute the processing corresponding to the non-specific control, The work area 223 for non-specific control and the stack area 224 for non-specific control in the main RAM 65 are used.

The management RAM 241 is provided with a normal counter area 231, an opening/closing execution mode counter area 232, a high frequency support mode counter area 233, and a calculation result storage area 234. The contents of these areas 231 to 234 are the same as those in the fifteenth embodiment. Also in this embodiment, the management execution process including the check process is executed as the process corresponding to the non-specific control in the main CPU 63. Then, in the check process, similar to the fifteenth embodiment, the game history is collected by updating the normal counter area 231, the opening/closing execution mode counter area 232, and the high frequency support mode counter area 233, and at the same time, the game history is collected. The 61st to 68th parameters calculated using the collected game history are written in the calculation result storage area 234. That is, the management RAM 241 is used when the main CPU 63 executes the process corresponding to the non-specific control, and thus the management RAM 241 is used as a work area for the non-specific control.

In addition, when the 61st to 68th parameters are calculated using the collected game history and the collected history information, the non-specific control work area 223 and the non-specific control stack area 224 of the main RAM 65 are Used as appropriate.

According to the above configuration, the normal counter area 231, the open/close execution mode counter area 232, the high frequency support mode counter area 233, and the calculation result storage area 234 are provided in the management RAM 241 externally attached to the MPU 62. This makes it possible to store the collected game history information while not increasing the storage capacity required in the work area 223 for non-specific control in the main RAM 65, and use the game history. It is possible to store the calculated 61st to 68th parameters. Further, it becomes possible to increase the storage capacity for storing the information of the game history while using the general-purpose MPU 62.

The non-specific control work area 223 and the non-specific control stack area 224 of the main RAM 65 are appropriately used when collecting the game history and calculating the 61st to 68th parameters using the collected history information. To be done. As a result, it is possible to prevent the processing speed from extremely decreasing when executing the processing related to the history information.

In addition to or in place of the configuration in which the normal RAM counter area 231, the open/close execution mode counter area 232, the high frequency support mode counter area 233, and the calculation result storage area 234 are provided in the management RAM 241, the first embodiment described above is used. A storage area corresponding to the history memory 117 in the form may be set. In this case, although it is necessary to increase the storage capacity required to store the history information, the management RAM 241 externally attached to the MPU 62 is used as a storage unit for storing the history information. Therefore, it is possible to flexibly cope with an increase in storage capacity.

<Twenty-second Embodiment>
In this embodiment, the processing configuration executed by the main CPU 63 is different from that of the fifteenth embodiment. Hereinafter, a configuration different from that of the fifteenth embodiment will be described. The description of the same configuration as the fifteenth embodiment is basically omitted.

FIG. 84 is a flowchart showing the main processing executed in the main CPU 63 in this embodiment. The processes of steps S5001 to S5019 in the main process are executed by the main CPU 63 using the specific control program and the specific control data.

First, power-on wait processing is executed (step S5001). In the power-on wait process, for example, the main process is started and waits for a predetermined time for waiting (specifically, 1 second) without proceeding to the next process. During the execution period of the power-on weight process, the operation start and initial setting of the symbol display device 41 are completed. After that, access to the main RAM 65 is permitted (step S5002).

After that, it is determined whether or not the reset button 68c has been pressed (step S5003), and it is determined whether or not the setting key insertion portion 68a has been turned on using the setting key (step S5004), and the inner frame It is determined with respect to 13 whether the front door frame 14 is in the open state (step S5005), and it is determined with respect to the outer frame 11 whether the gaming machine main body 12 is in the open state (step S5006).

In the present embodiment, a front door opening sensor 95 for detecting whether or not the front door frame 14 is opened with respect to the inner frame 13 is electrically connected to the main CPU 63, and the front door opening sensor The detection result of 95 is input to the main CPU 63. In this case, when the front door frame 14 is closed with respect to the inner frame 13, the front door open sensor 95 transmits a close detection signal to the main CPU 63, and the front door frame 14 is opened with respect to the inner frame 13. In the case of, the front door opening sensor 95 sends an opening detection signal to the main CPU 63. The main CPU 63 specifies that the front door frame 14 is in the closed state when receiving the closing detection signal from the front door opening sensor 95, and when receiving the opening detection signal from the front door opening sensor 95. The front door frame 14 is specified to be in the open state.

Further, in the present embodiment, a main body opening sensor 96 for detecting whether or not the gaming machine main body 12 is in an open state with respect to the outer frame 11 is electrically connected to the main CPU 63, and the main body opening sensor The detection result of 96 is input to the main CPU 63. In this case, when the gaming machine main body 12 is closed with respect to the outer frame 11, the main body opening sensor 96 transmits a closing detection signal to the main CPU 63, and the gaming machine main body 12 is opened with respect to the outer frame 11. In some cases, the main body open sensor 96 sends an open detection signal to the main CPU 63. The main CPU 63 specifies that the gaming machine main body 12 is in the closed state when receiving the closing detection signal from the main body opening sensor 96, and determines when the opening detection signal is received from the main body opening sensor 96. It specifies that the main body 12 is in the open state.

When the reset button 68c is being pressed (step S5003: YES) and a negative determination is made in any of steps S5004 to S5006, a clear process at the time of non-setting update is executed (step S5007). .. In the clear processing at the time of non-setting update, the specific control is performed except for the area (specifically, the set value counter) in the work area 221 for the specific control in which the setting value information indicating the setting state of the pachinko machine 10 is set. The work area 221 for use is cleared to "0", and the area cleared to "0" is initialized. As a result, the area indicating whether or not the winning/winning lottery mode is the high-probability mode is cleared to "0". The mode is a low probability mode. In addition, the game times are not being executed, the opening/closing execution mode is not being executed, and the general-purpose display unit 38a is not being variably displayed, and the general electric accessory 34a is in the closed state. It becomes a situation. Further, since the hold storage area 65a and the universal electric power reserve area 65c provided in the work area 221 for specific control are also cleared to "0", the reserved information for the special figure display portion 37a is deleted and the general figure display portion is deleted. The hold information for 38a is deleted. In addition, in the clear processing at the time of non-setting update, the stack area 222 for specific control is cleared to “0”. In addition, in the clear processing at the time of non-setting update, various registers of the main CPU 63 are also cleared to “0” and then initialized.

In the clear processing at the time of non-setting update, the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to "0". As a result, even if supply of operating power to the pachinko machine 10 is started with the reset button 68c being pressed, the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to "0". It becomes possible to do so.

When the reset button 68c has not been pressed (step S5003: NO), it is determined whether the power failure flag is set to "1" (step S5008). The power failure flag is provided in the work area 221 for specific control, and when the supply of operating power to the main CPU 63 is stopped and a predetermined power failure process is normally executed, the power failure flag is set. Will be set to "1". When the power failure flag is set to "1", it is determined whether or not the checksum calculation result matches the checksum saved when the power is cut off, that is, the validity of the stored data is determined (step S5009). .. When the clear processing at the time of non-setting update is executed in step S5007 or when the positive determination is made in step S5009, the setting of the pachinko machine 10 is confirmed by checking the value of the set value counter in the work area 221 for specific control. It is determined whether the value is normal (step S5010). Specifically, when the set value set in the set value counter is any of "setting 1" to "setting 6", it is determined to be normal, and when it is "0" or 7 or more, there is an abnormality. Judge that there is.

If a negative determination is made in any of steps S5008 to S5010, operation prohibition processing is executed. In the operation prohibiting process, an infinite loop is performed after executing the error notifying process for notifying the hall manager or the like of the occurrence of the error (step S5011). The operation prohibition process is canceled by executing a clearing process (step S5018) at the time of updating the setting, which will be described later.

When a positive determination is made in all of steps S5008 to S5010, power-on setting processing is executed (step S5012). In the power-on setting process, a predetermined area of the work area 221 for specific control such as initialization of the power failure flag is set to an initial value, and a command corresponding to the current game state is transmitted to the voice emission control device 81.

Although the main CPU 63 is configured to periodically execute the timer interrupt process, the generation of the timer interrupt process is prohibited when the main process is started. The state in which the generation of the timer interrupt process is prohibited is released at the timing before the process of step S5012 is completed and the process of step S5013 is executed, and the execution of the timer interrupt process is permitted. As a result, when the supply of the operating power to the main CPU 63 is started, the power-on setting process of step S5012 ends, and the timer interrupt process is not executed until the stage before the process of step S5013 is started. Therefore, the processing for advancing the game in the main CPU 63 is not started until this situation is reached.

After that, the process proceeds to the residual process of steps S5013 to S5016. That is, the main CPU 63 is configured to periodically execute the timer interrupt process, but a residual time is generated between one timer interrupt process and the next timer interrupt process. This remaining time will vary depending on the processing completion time of each timer interrupt processing, but the remaining processing of steps S5013 to S5016 is repeatedly executed using this irregular time. In this respect, it can be said that the residual process of steps S5013 to S5016 is an irregular process that is irregularly executed. In steps S5013 to S5016, the same processing as steps S113 to S116 of the main processing (FIG. 9) in the first embodiment is executed.

On the other hand, when the reset button 68c is being pressed (step S5003: YES) and a positive determination is made in all of steps S5004 to S5006, processing for updating the set value is executed. Specifically, first, a setting value copy process is executed (step S5017). In the copy processing, information on a setting value counter used to specify the setting value of the pachinko machine 10 in the specific control work area 221 is stored in a copy area provided in the specific control work area 221. .. As a result, even if the setting value counter information is cleared to "0" in the subsequent clearing process at the time of updating the setting (step S5018), the book before the clearing process at the time of updating the setting value is executed. It is possible to grasp the set value of the pachinko machine 10 (that is, the set value of the pachinko machine 10 before the supply of the operating power to the pachinko machine 10 is stopped).

After that, a clear process at the time of updating the setting is executed (step S5018). In the clear process at the time of updating the setting, the work area 221 for the specific control is set to “0” except for the area indicating whether the win/loss lot mode in the work area 221 for the specific control is the high probability mode and the copy area. The area which has been cleared to "0" is initialized. As a result, the game times are not being executed, the opening/closing execution mode is not being executed, and the general-purpose display unit 38a is not being variably displayed, and the general electric accessory 34a is in the closed state. There is a certain situation. Further, since the hold storage area 65a and the universal electric power reserve area 65c provided in the work area 221 for specific control are also cleared to "0", the reserved information for the special figure display section 37a is deleted and the general figure display section is deleted. The hold information for 38a is deleted. Further, in the clearing process at the time of updating the settings, the stack area 222 for specific control is cleared to “0”, and the area cleared to “0” is initialized. Further, in the clearing process at the time of updating the setting, the setting value counter used for specifying the setting value of the pachinko machine 10 is cleared to “0”. Further, in the clearing process at the time of updating the settings, various registers of the main CPU 63 are also cleared to “0” and then initialized.

On the other hand, in the clear process at the time of updating the settings, the area indicating whether or not the winning/winning lottery mode is the high-probability mode is not cleared to “0”, so that the winning/winning lottery mode is executed even if the setting value updating process (step S5019) is executed. Can be maintained in the mode before the supply of the operating power to the pachinko machine 10 is stopped. In addition, since the copy area is not cleared to "0" in the clearing process at the time of setting update, it is possible to specify the set value set before the clearing process at the time of setting update is executed.

In the clear processing at the time of updating the settings, the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to "0". As a result, even if the setting value updating process capable of changing the setting value of the pachinko machine 10 is executed, the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to "0". It becomes possible to do so.

After that, after executing the setting value update process in step S5019, the process proceeds to step S5012. The setting value update process will be described below. FIG. 85 is a flowchart showing the set value updating process. The processing of steps S5101 to S5114 in the setting value update processing is executed by the main CPU 63 using the specific control program and the specific control data.

First, "1" is set to the set value counter provided in the work area 221 for specific control (step S5101). The set value counter is a counter for the main CPU 63 to specify which set value the set state of the pachinko machine 10 is. By setting "1" in the set value counter, when the set value updating process is executed, the set value becomes "set 1" regardless of the set value up to that point.

After that, display start processing of the set value is executed (step S5102). In the setting value display start processing, the display of the third notification display device 69c is controlled so that the number "1" corresponding to "Setting 1" is displayed. When changing the set value, the manager of the game hall can confirm the current setting state of the pachinko machine 10 by checking the third notification display device 69c.

After that, it is determined whether or not one gaming ball is detected by the out mouth detection sensor 48a (step S5103). Specifically, it is determined whether or not the signal received from the outlet detection sensor 48a has switched from the LOW level to the HI level. When a negative determination is made in step S5103, it is determined whether or not the update button 68b has been pressed once (step S5104). Specifically, it is determined whether or not the signal from the sensor that detects the pressing operation of the update button 68b has switched from the LOW level to the HI level. When a negative determination is made in step S5104, the process returns to step S5103 and it is determined whether or not one gaming ball is detected by the out-mouth detection sensor 48a.

When the update button 68b is pressed once (step S5104: YES), the value of the set value counter in the work area 221 for specific control is incremented by 1 (step S5105). When the value of the set value counter after adding 1 exceeds "6" (step S5106: YES), "1" is set in the set value counter (step S5107). As a result, each time the update button 68b is pressed once, it is updated to the set value one step higher, and when the update button 68b is pressed once in the situation of "setting 6", it is set to "setting 1". Will return.

If a negative determination is made in step S5106, or if the processing of step S5107 is executed, display update processing of the set value is executed (step S5108). In the display update process of the set value, the display control of the third notification display device 69c is performed so that the number corresponding to the value of the set value counter in the specific control work area 221 is displayed. By checking the third notification display device 69c, the manager of the game hall can grasp the setting state of the pachinko machine 10 after pressing the update button 68b.

After executing the process of step S5108, the process returns to step S5103, and it is determined whether or not one gaming ball is detected by the out-mouth detection sensor 48a. When one gaming ball is not detected by the out-mouth detection sensor 48a (step S5103: NO), the processes after step S5104 are executed again. When one gaming ball is detected by the out-mouth detection sensor 48a (step S5103: YES), it is determined whether the setting key insertion part 68a has been switched from the ON state to the OFF state (step S5109). In this case, it is not specified whether or not the setting key insertion unit 68a is in the OFF state, but it is specified whether or not the switching from the ON state to the OFF state has occurred, and that the switching has occurred. If specified, an affirmative decision is made in step S5109.

If it has not been switched to the OFF state (step S5109: NO), the process of step S5109 is executed again. As a result, the process is on standby until the setting key insertion unit 68a is turned off. When it is switched to the OFF state (step S5109: YES), display end processing of the set value is executed (step S5110). In the display end processing of the set value, the display of the set value on the third notification display device 69c is ended. In this case, the display of the information of various parameters stored in the calculation result storage area 234 provided in the non-specific control work area 223 is started on the first to third notification display devices 69a to 69c.

After that, a comparison process of set values is executed (step S5111). In the setting value comparison processing, it is determined whether or not the information of the setting value counter in the specific control work area 221 matches the information stored in the copy area in the specific control work area 221. That is, it is determined whether or not the set value set before the supply of the operating power to the pachinko machine 10 is stopped and the set value set in the set value update process this time.

When the set value set before the supply of the operating power to the pachinko machine 10 is stopped and the set value set in the set value updating process this time are the same (step S5112: NO), non- The notification process at the time of change is executed (step S5113). In the notification process at the time of non-change, a setting maintenance command indicating that the set value has not been changed is transmitted to the sound emission control device 81. Upon receiving the setting maintaining command, the sound emission control device 81 causes the display light emitting unit 53 to emit light in a mode corresponding to the setting maintaining, and causes the speaker unit 54 to output the sound “Setting is maintained”. Further, the character image of "Maintain settings" is displayed on the symbol display device 41.

These notifications are maintained until the notification execution period (for example, 10 seconds) elapses after the setting maintenance command is transmitted, and is terminated when the notification execution period has elapsed. However, the present invention is not limited to this, and the notification may be ended when the notification end operation is performed by the game hall manager. As the notification end operation, for example, the update button 68b may be pressed or the reset button 68c may be pressed. By confirming the notification, the manager of the game hall can understand that the set value has been maintained. In the notification process during non-change, the set value is maintained by setting the display content on at least one of the first to third display devices 69a to 69c as the display content corresponding to the setting maintenance. It may be configured to notify that, or may be configured to perform external output indicating that the set value is maintained.

If the set value set before the supply of the operating power to the pachinko machine 10 is stopped is not the same as the set value set in the current set value updating process (step S5112: YES), change The notification processing for the hour is executed (step S5114). In the notification process at the time of change, a setting change command indicating that the set value has been changed is transmitted to the sound emission control device 81. Upon receiving the setting change command, the sound emission control device 81 causes the display light emitting unit 53 to emit light in a manner corresponding to the setting change, and causes the speaker unit 54 to output a sound of “setting change”. In addition, the character image of “setting change” is displayed on the symbol display device 41.

These notifications are maintained until the notification execution period (for example, 10 seconds) elapses after the setting change command is transmitted, and is terminated when the notification execution period has elapsed. However, the present invention is not limited to this, and the notification may be ended when the notification end operation is performed by the game hall manager. As the notification end operation, for example, the update button 68b may be pressed or the reset button 68c may be pressed. By confirming the above notification, the game hall manager can recognize that the set value has been changed. In the notification process at the time of change, the set value is changed by setting the display content of at least one of the first to third display devices 69a to 69c as the display content corresponding to the setting change. May be informed, or an external output indicating that the set value has been changed may be performed.

As described above, in the present embodiment, in order to execute the set value updating process, not only the setting key insertion portion 68a is turned on, but also the reset button 68c is pressed and the front door frame 14 is in the open state. Therefore, the gaming machine main body 12 needs to be in an open state. As a result, it becomes possible to make it difficult to execute the set value updating process illegally.

Further, the front door frame 14 and the gaming machine main body 12 need to be in an open state in order to execute the set value updating process. As a result, even if the setting value updating process is attempted to be illegally executed, the fraudulent act becomes noticeable because the front door frame 14 and the gaming machine main body 12 are in the open state, and the manager of the gaming hall concerned It's easier to find fraud.

In particular, in order to execute the set value updating process, not only the opening operation of the gaming machine main body 12 necessary for exposing the main control device 60 but also the opening operation of the front door frame 14 is required. It becomes possible to make the work of the fraudulent operation complicated and to make the fraudulent activity noticeable.

Further, in the configuration that does not return to the process for advancing the game when the set value update process is not completed, in order to confirm the set value selected in the set value update process and end the set value update process, It is necessary to insert a game ball into the outlet 24a and cause the outlet detection sensor 48a to detect the game ball, and then turn off the setting key insertion portion 68a. As a result, even if the setting value updating process is illegally executed, it is possible to make it difficult to perform an operation for subsequently ending the setting value updating process and returning to the process for advancing the game.

In addition, the set value set before the supply of the operating power to the pachinko machine 10 is stopped and the set value selected in the set value updating process are compared to determine whether or not both set values are the same. The notification corresponding to the crab is executed. Thereby, the manager of the game hall can easily grasp whether or not the set value can be changed by the set value updating process.

FIG. 86 is a flowchart showing the timer interrupt processing executed in the main CPU 63 in this embodiment. The timer interrupt process is executed periodically (for example, every 4 milliseconds) in a situation where the processes of steps S5013 to S5016 are executed in the main process (FIG. 84). The program corresponding to the timer interrupt process is set to the program for specific control.

In steps S5201 to S5205, the same processes as steps S301 to S305 of the timer interrupt process (FIG. 11) in the first embodiment are executed. These processes are executed by the main CPU 63 using a specific control program and specific control data.

After that, a setting confirmation process is executed (step S5206). When executing the setting confirmation process, the subroutine program corresponding to the setting confirmation process set in the specific control program is executed. However, when executing the subroutine program, the setting confirmation process is executed. The information for specifying the return address of the timer interrupt process after execution of is written into the stack area 222 for specific control by the push command. Then, when the setting confirmation processing is completed, the information for specifying the return address is read by the pop instruction, and the program returns to the timer interrupt processing program indicated by the return address.

FIG. 87 is a flowchart showing the setting confirmation processing. The processes of steps S5301 to S5312 in the setting confirmation process are executed by the main CPU 63 using the specific control program and the specific control data.

First, it is determined whether or not the set value corresponding to the set value counter information in the specific control work area 221 is being displayed on the third notification display device 69c (step S5301). When a negative determination is made in step S5301, it is determined whether it is neither the game time nor the open/close execution mode (step S5302), and the variable display time of the pattern on the universal figure display portion 38a and the universal electric utility article 34a are opened. It is determined whether or not it is any of the normal electric open states that can be the state (step S5303), and it is determined whether the front door frame 14 is in the open state with respect to the inner frame 13 (step S5304), and the outer frame. It is determined whether the gaming machine main body 12 is in the open state with respect to 11 (step S5305), and it is determined whether the setting key insertion portion 68a is turned on (step S5306). Whether or not the front door frame 14 is in the open state is determined based on the detection result of the front door open sensor 95 similarly to step S5005 in the main process (FIG. 84), and whether or not the gaming machine main body 12 is in the open state. This determination is made based on the detection result of the main body open sensor 96, as in step S5006 in the main process (FIG. 84).

When a negative determination is made in any of steps S5302 to S5306, this setting confirmation process is terminated without executing the processes of steps S5307 to S5309. When a positive determination is made in all of steps S5302 to S5306, setting value display start processing is executed (step S5307). In the set value display start processing, the third notification display device 69c is display-controlled so that the set value number corresponding to the information of the set value counter in the specific control work area 221 is displayed. When confirming the setting value, the manager of the gaming hall can grasp the current setting state of the pachinko machine 10 by visually checking the third notification display device 69c.

Then, "1" is set to the game stop flag provided in the work area 221 for specific control (step S5308). The game stop flag is a situation in which a positive determination is made in step S5207 in the timer interrupt processing (FIG. 86) and the processing of steps S5208 to S5221 is not executed, that is, the execution of processing for advancing the game should be stopped. This is a flag for the main CPU 63 to specify whether or not there is. When the game stop flag is set to "1", an affirmative determination is made in step S5207 of the timer interrupt processing (FIG. 86), and the processing in steps S5208 to S5221 is not executed. As a result, the setting value is confirmed in the situation where the execution of the process for advancing the game is stopped. However, even if the game stop flag is set to "1", the processing of steps S5201 to S5205 in the timer interrupt processing (FIG. 86) is executed, so that the setting value is being confirmed. Even when the power failure is monitored, the winning random number counter C1, the big hit type counter C2, the reach random number counter C3, and the random number initial value counter CINI are updated, and further fraud detection is executed.

After that, the confirmation notification start command is transmitted to the voice emission control device 81 (step S5309). Upon receiving the confirmation notification start command, the voice emission control device 81 causes the display light emitting unit 53 to emit light in a manner corresponding to the setting confirmation, and causes the speaker unit 54 to output the voice “Setting confirmation is in progress”. .. Further, the symbol display device 41 is made to display a character image "Setting confirmation is in progress." These notifications are continued until the confirmation notification end command is received from the main CPU 63. Note that a configuration may be adopted in which external output indicating that the setting value is being confirmed is performed.

As described above, on condition that it is neither the game times nor the opening/closing execution mode, and further, neither the variable display times of the picture in the universal figure display portion 38a nor the universal electric open state in which the general electric accessory 34a can be in the opened state, Since the display for confirming the set value is displayed on the third notification display device 69c, it is possible to prevent the set value confirmation work from being performed in the situation where the game is being played. It will be possible.

Moreover, in order to display the confirmation of the set value on the third notification display device 69c, not only the setting key insertion portion 68a is turned on, but also the front door frame 14 is opened. Therefore, the gaming machine main body 12 needs to be in an open state. As a result, even if an attempt is made to illegally display the setting value for confirmation, it is difficult to do so.

Further, in order for the display for confirming the set value to be displayed on the third notification display device 69c, the front door frame 14 and the gaming machine main body 12 need to be open. As a result, even if an attempt is made to illegally display the set value for confirmation, since the front door frame 14 and the gaming machine main body 12 are in an open state, the fraudulent act becomes conspicuous, and the management of the gaming hall is performed. It becomes easier for a person to discover the wrongdoing.

In particular, in order for the display for confirming the set value to be displayed on the third notification display device 69c, not only the opening operation of the gaming machine main body 12 necessary for exposing the main control device 60, Since the opening operation of the front door frame 14 is also required, it becomes possible to complicate the work of the fraudulent act and make the fraudulent act conspicuous.

If an affirmative decision is made in step S5301, it is decided whether or not the setting key insertion part 68a has been turned off (step S5310). If the OFF operation has been performed (step S5310: YES), the game stop flag in the specific control work area 221 is cleared to "0" (step S5311). As a result, a negative determination is made in step S5207 of the timer interrupt processing (FIG. 86), and the processing in steps S5208 to S5221 is executed. As a result, the state in which the execution of the process for advancing the game is stopped is released.

After that, the confirmation notification end command is transmitted to the voice emission control device 81 (step S5312). Upon receiving the confirmation notification end command, the voice emission control device 81 ends the notification indicating that the setting values in the symbol display device 41, the display light emitting unit 53, and the speaker unit 54 are being confirmed.

Returning to the explanation of the timer interrupt process (FIG. 86), after ending the setting confirmation process of step S5206, it is determined whether or not the game is stopped (step S5207). In this case, if the game stop flag in the specific control work area 221 is set to "1" in the setting confirmation process of step S5206, an affirmative decision is made in step S5207, and steps S5208 to S5221 are executed. Do not execute the process. Further, even when the occurrence of fraud is detected in the fraud detection processing in step S5205, a positive determination is made in step S5207, and the processing in steps S5208 to S5221 is not executed.

In steps S5208 to S5219, the same processes as steps S307 to S318 of the timer interrupt process (FIG. 11) in the first embodiment are executed. These processes are executed by the main CPU 63 using a specific control program and specific control data. Further, in step S5221, the same process as step S3719 of the timer interrupt process (FIG. 69) in the fifteenth embodiment is executed.

On the other hand, in step S5220, RAM monitoring processing is executed. When executing the RAM monitoring process, the program of the subroutine corresponding to the RAM monitoring process set in the program for specific control is executed. However, when executing the program of the subroutine, after executing the RAM monitoring process. The information for specifying the return address of the timer interrupt process in is written in the stack area 222 for specific control by the push command. When the RAM monitoring process is completed, the pop instruction reads the information for identifying the return address, and the program returns to the timer interrupt process program indicated by the return address.

FIG. 88 is a flowchart showing the RAM monitoring process. The processes of steps S5401 to S5412 in the RAM monitoring process are executed by the main CPU 63 using the specific control program and the specific control data.

First, the monitoring process of the work area 221 for specific control is executed (step S5401). In the monitoring process, it is monitored whether or not the information stored in the specific control work area 221 is abnormal due to noise or the like. Although this monitoring method is arbitrary, for example, in the work area 221 for specific control, whether the state of the storage area in which information is not written by various controls in the main CPU 63 is different from the initial state is determined. There is a method of observing, and determining that an abnormality has occurred when the state is different from the initial state. In this case, if the initial state of the storage area is set to a value of "0", it is determined that an abnormality has occurred when "1" is stored in the storage area, and the initial state of the storage area is "1". When the value is “0”, it is determined that an abnormality has occurred when the storage area has a value of “0”. In addition to the above monitoring method, it may be configured to determine that an abnormality has occurred when the value of a predetermined byte is different from the value that can be set in a normal state.

If it is determined that there is an abnormality in step S5401 (step S5402: YES), the processes of steps S5409 to S5412 are executed. If it is not determined that there is an abnormality in step S5401 (step S5402: NO), the process proceeds to step S5403.

In step S5403, monitoring processing of the stack area 222 for specific control is executed. In the monitoring process, it is monitored whether or not the information stored in the stack area 222 for specific control is abnormal due to noise or the like. Although this monitoring method is arbitrary, for example, in the stack area 222 for specific control, whether or not the state of the storage area where information is not written by various controls in the main CPU 63 is different from the initial state There is a method of observing, and determining that an abnormality has occurred when the state is different from the initial state. In this case, if the initial state of the storage area is set to a value of "0", it is determined that an abnormality has occurred when "1" is stored in the storage area, and the initial state of the storage area is "1". When the value is “0”, it is determined that an abnormality has occurred when the storage area has a value of “0”. In addition to the above monitoring method, it may be configured to determine that an abnormality has occurred when the value of a predetermined byte is different from the value that can be set in a normal state.

When it is determined that there is an abnormality in step S5403 (step S5404: YES), the processes of steps S5409 to S5412 are executed. If it is not determined that there is an abnormality in step S5403 (step S5404: NO), the process proceeds to step S5405.

In step S5405, monitoring processing of the work area 223 for non-specific control is executed. In the monitoring process, it is monitored whether or not the information stored in the work area 223 for non-specific control is abnormal due to noise or the like. Although this monitoring method is arbitrary, for example, in the work area 223 for non-specific control, whether the state of the storage area in which information is not written by various controls in the main CPU 63 is different from the initial state There is a method of monitoring whether or not and determining that an abnormality has occurred when the state is different from the initial state. In this case, if the initial state of the storage area is set to a value of "0", it is determined that an abnormality has occurred when "1" is stored in the storage area, and the initial state of the storage area is "1". When the value is “0”, it is determined that an abnormality has occurred when the storage area has a value of “0”. In addition to the above monitoring method, it may be configured to determine that an abnormality has occurred when the value of a predetermined byte is different from the value that can be set in a normal state.

When it is determined that there is an abnormality in step S5405 (step S5406: YES), the processes of steps S5409 to S5412 are executed. If it is not determined that there is an abnormality in step S5405 (step S5406: NO), the process proceeds to step S5407.

In step S5407, monitoring processing of the stack area 224 for non-specific control is executed. In the monitoring process, it is monitored whether information stored in the non-specific control stack area 224 is abnormal due to noise or the like. Although this monitoring method is arbitrary, for example, in the stack area 224 for non-specific control, whether the state of the storage area in which information is not written under various controls in the main CPU 63 is different from the initial state There is a method of monitoring whether or not and determining that an abnormality has occurred when the state is different from the initial state. In this case, if the initial state of the storage area is set to a value of "0", it is determined that an abnormality has occurred when "1" is stored in the storage area, and the initial state of the storage area is "1". When the value is “0”, it is determined that an abnormality has occurred when the storage area has a value of “0”. In addition to the above monitoring method, it may be configured to determine that an abnormality has occurred when the value of a predetermined byte is different from the value that can be set in a normal state.

When it is determined that there is an abnormality in step S5407 (step S5408: YES), the processes of steps S5409 to S5412 are executed. Specifically, first, a setting value copy process is executed (step S5409). In the copy processing, information on a setting value counter used to specify the setting value of the pachinko machine 10 in the specific control work area 221 is stored in a copy area provided in the specific control work area 221. .. As a result, even if the setting value counter information is cleared to "0" in the abnormal clearing process (step S5410) executed thereafter, the pachinko machine 10 before the abnormal clearing process is executed. It becomes possible to grasp the set value of.

After that, the clear processing at the time of abnormality is executed (step S5410). In the clear processing at the time of abnormality, the work area 221 for specific control except for the copy area is cleared to “0”, and the stack area 222 for specific control, the work area 223 for non-specific control and the stack for non-specific control are provided. The area 224 is cleared to "0". Also, after "0" is cleared, initial setting is performed. That is, in the RAM monitoring process, an abnormality occurs in any one of the specific control work area 221, the specific control stack area 222, the non-specific control work area 223, and the non-specific control stack area 224. If it is specified that the work area 221 for specific control is cleared to “0” except for the copy area, the stack area 222 for specific control, the work area 223 for non-specific control, and the non-specific control Clear the stack area 224 of "0". As a result, if there is a possibility that some sort of information abnormality has occurred in the main RAM 65, neither the processing corresponding to the specific control nor the processing corresponding to the non-specific control will be executed in that state. It becomes possible to do so.

When the stack area 222 for specific control is cleared to “0”, the information on the return address after the RAM monitoring processing is also erased. Therefore, when the stack area 222 for specific control is cleared to “0”, the process of step S5412 is terminated, and then a specific program is uniquely returned. Specifically, the processing is uniquely returned to the processing of step S5013 in the main processing (FIG. 22). However, the program that uniquely returns is not limited to step S5013, and may be step S5221 in the timer interrupt processing (FIG. 86). Further, when the stack area 222 for specific control is cleared to “0”, the stack pointer of the main CPU 63 is also set to the address of the first storage area in the storage order in the stack area 222 for specific control.

After that, an abnormal command indicating that the clear processing at the abnormal time has occurred is transmitted to the sound emission control device 81 (step S5411). Upon receiving the abnormal command, the voice emission control device 81 causes the display light emitting unit 53 to emit light in a mode corresponding to the forced clear, and causes the speaker unit 54 to output the voice “Forced clear.”. In addition, the character image "Forced clear." is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are ended when the supply of operating power to the pachinko machine 10 is stopped. However, the present invention is not limited to this, and the notification may be ended when the notification end operation is performed by the game hall manager. As the notification end operation, for example, the update button 68b may be pressed or the reset button 68c may be pressed. By confirming the notification, the game hall manager can grasp that the main RAM 65 has been forcibly cleared.

After that, the set value updating process is executed (step S5412). That is, when the clear processing at the time of abnormality occurs, "0" is cleared including the set value counter in the work area 221 for specific control, so that the set value of the pachinko machine 10 is reset. In order to do so, set value update processing is executed. The processing content of the setting value update processing is the same as step S5019 of the main processing (FIG. 84). Therefore, each time the update button 68b is pressed once, the set value is updated one step at a time, and the set value being selected is confirmed by detecting the game ball with the outlet detection sensor 48a. The set value that is being updated and the set value that has been confirmed are displayed on the third notification display device 69c. After that, when the setting key insertion unit 68a is switched from the ON state to the OFF state, it is determined that the ending condition of the set value updating process is satisfied.

Here, it is not determined that the termination condition is satisfied only by the setting key insertion portion 68a being in the OFF state, and the termination condition is determined when the setting key insertion portion 68a is switched from the ON state to the OFF state. It is determined that it has been established. When the setting value updating process is executed in the RAM monitoring process (FIG. 88), the setting key inserting unit 68a is in the OFF state at the start of the setting value updating process, and therefore the termination condition of the setting value updating process is set. In order to be satisfied, it is necessary to insert the setting key into the setting key insertion portion 68a, perform the ON operation once, and then perform the OFF operation. As a result, it becomes possible to prevent the setting value updating process from ending even though the game hall manager has not performed a regular operation.

When the setting key insertion unit 68a is switched from the ON state to the OFF state and the ending condition of the set value updating process is satisfied, by executing step S5111 in the set value updating process (FIG. 85), It is compared whether or not the set value stored in the copy area of the specific control work area 221 and the set value currently set in the set value counter in the specific control work area 221 are the same. That is, it is determined whether the set value set before the execution of the clear process (step S5410) at the time of abnormality is the same as the set value set in the set value update process this time. When both set values are the same (step S5112: NO), the notification process at the time of non-change (step S5113) is executed to perform the setting maintenance notification already described. On the other hand, when the two setting values are different (step S5112: YES), the notification process at the time of change (step S5114) is executed so that the setting change notification described above is performed.

According to this embodiment described in detail above, the following excellent effects are exhibited.

In order to execute the set value updating process when the supply of the operating power to the pachinko machine 10 is started, not only the setting key insertion section 68a is turned on but also the reset button 68c is pressed. The front door frame 14 needs to be in the open state, and the gaming machine body 12 needs to be in the open state. As a result, it becomes possible to make it difficult to execute the set value updating process illegally.

In order to execute the set value updating process, the front door frame 14 and the gaming machine main body 12 need to be in an open state. As a result, even if the setting value updating process is attempted to be illegally executed, the fraudulent act becomes noticeable because the front door frame 14 and the gaming machine main body 12 are in the open state, and the manager of the gaming hall concerned It's easier to find fraud.

In particular, in order to execute the set value updating process, not only the opening operation of the gaming machine main body 12 necessary for exposing the main control device 60 but also the opening operation of the front door frame 14 is required. It becomes possible to make the work of the fraudulent operation complicated and to make the fraudulent activity noticeable.

When the set value update process is not completed, in the configuration that does not return to the process for advancing the game, in order to confirm the set value selected in the set value update process and terminate the set value update process, It is necessary to insert a game ball into 24a and have the outlet detection sensor 48a detect the game ball, and then turn off the setting key insertion portion 68a. As a result, even if the setting value updating process is illegally executed, it is possible to make it difficult to perform an operation for subsequently ending the setting value updating process and returning to the process for advancing the game.

The set value that was set before the supply of the operating power to the pachinko machine 10 was stopped and the set value that was selected in the set value update processing are compared to determine whether the two set values are the same. The corresponding notification is executed. Thereby, the manager of the game hall can easily grasp whether or not the set value can be changed by the set value updating process.

The setting value is set on the condition that neither the game time nor the opening/closing execution mode is set, and further, neither the variable display time of the picture on the universal figure display portion 38a nor the universal electric open state in which the general electric accessory 34a can be opened. By making the display for confirmation displayed on the third notification display device 69c, it becomes possible to prevent confirmation work of the set value from being performed in a situation where a game is being played. ..

In order for the display for confirming the set value to be displayed on the third notification display device 69c, not only the setting key insertion portion 68a is turned on, but the front door frame 14 is opened. Therefore, the gaming machine main body 12 needs to be in an open state. As a result, even if an attempt is made to illegally display the setting value for confirmation, it is difficult to do so.

In order for the display for confirming the set value to be displayed on the third notification display device 69c, the front door frame 14 and the gaming machine main body 12 need to be open. As a result, even if an attempt is made to illegally display the set value for confirmation, since the front door frame 14 and the gaming machine main body 12 are in an open state, the fraudulent act becomes conspicuous, and the management of the gaming hall is performed. It becomes easier for a person to discover the wrongdoing.

In particular, in order for the display for confirming the set value to be displayed on the third notification display device 69c, not only the opening operation of the gaming machine main body 12 necessary for exposing the main control device 60, Since the opening operation of the front door frame 14 is also required, it becomes possible to complicate the work of the fraudulent act and make the fraudulent act conspicuous.

When it is specified that an abnormality has occurred in any one of the specific control work area 221, the specific control stack area 222, the non-specific control work area 223, and the non-specific control stack area 224. Clears the work area 221 for specific control excluding the copy area to "0", and sets the stack area 222 for specific control, the work area 223 for non-specific control and the stack area 224 for non-specific control to "0". "clear. As a result, when there is a possibility that some sort of information abnormality has occurred in the main RAM 65, both the processing corresponding to the specific control and the processing corresponding to the non-specific control are executed in that state. It is possible to prevent it.

In the process corresponding to the specific control, information abnormality occurs not only in the specific control work area 221 and the specific control stack area 222, but also in the non-specific control work area 223 and the non-specific control stack area 224. Whether or not it is monitored. As a result, the processing configuration can be simplified as compared with the configuration in which the process corresponding to the specific control and the process corresponding to the non-specific control are separately monitored for whether or not an information abnormality has occurred.

When it is specified that an abnormality has occurred in any one of the specific control work area 221, the specific control stack area 222, the non-specific control work area 223, and the non-specific control stack area 224. In the process corresponding to the specific control, not only the work area 221 for the specific control and the stack area 222 for the specific control but also the work area 223 for the non-specific control and the stack area 224 for the non-specific control are “0. It will be cleared. As a result, the processing configuration can be simplified as compared with the configuration in which the processing corresponding to the specific control and the processing corresponding to the non-specific control are separately performed to clear “0”.

When the clear processing at the time of abnormality is executed due to the occurrence of the information abnormality, the set value update processing is executed. As a result, it is possible to prevent the game from proceeding even though the set value is not set. In this case, if the set value that was set before the abnormal clearing process was executed is the same as the setting value that was set in the set value update process after the abnormal clearing process was executed. Is notified of setting maintenance. As a result, even if the clear processing at the time of abnormality is executed, the setting maintenance notification will be performed by resetting the setting value set in the previous situation, and the clear processing at the time of abnormality will be executed. Also, it becomes possible to clearly indicate to the player that the set value has not changed. By the way, since it is common to record the set value of each pachinko machine 10 installed in the game hall, the set value update process after the execution of the clear process at the time of abnormality so that the recorded set value becomes the recorded set value. Can be performed.

It should be noted that the condition for executing the set value updating process when the supply of the operating power to the pachinko machine 10 is started may be a condition different from the above embodiment. FIG. 89 is a flowchart showing a main process which is another form. In the main processing, the same processing as steps S5001 to S5019 of the main processing (FIG. 84) in the above embodiment is executed in steps S5501 to S5506 and steps S5508 to S5520. On the other hand, in the main processing, in step S5507, it is determined whether or not the operation handle of the firing operation device 28 that is operated to fire the game ball in the game area PA has been rotated from the initial rotation position. Then, the reset button 68c is pressed (step S5503: YES), the setting key insertion part 68a is turned on (step S5504: YES), and the front door frame 14 is opened with respect to the inner frame 13. (Step S5505: YES), the gaming machine main body 12 is opened with respect to the outer frame 11 (Step S5506: YES), and the operation handle of the firing operation device 28 is rotated from the initial rotation position. If so (step S5507: YES), the set value updating process (step S5520) is executed. Accordingly, in order to execute the set value updating process when the supply of the operating power to the pachinko machine 10 is started, not only the setting key is inserted into the setting key insertion section 68a and the ON operation is performed, but also the firing is performed. It is necessary to start supplying the operating power to the pachinko machine 10 in a state where the operation handle of the operation device 28 is rotated. Therefore, it becomes possible to make it difficult to perform an act of illegally changing the set value. It should be noted that, in step S5507, it is not determined whether the operation handle of the firing operation device 28 is rotated from the initial rotation position, but it is determined whether the firing operation device 28 is touched by the player. It may be configured.

Further, as a condition for executing the set value updating process when the supply of operating power to the pachinko machine 10 is started, the front door frame 14 is in an open state with respect to the inner frame 13 and the outside Although both of the conditions that the gaming machine main body 12 is in the open state are set for the frame 11, only one of these conditions may be set.

Further, the condition that the reset button 68c is pressed is set as the condition for executing the set value updating process when the supply of the operating power to the pachinko machine 10 is started. However, the condition may not be set.

Further, as a condition for executing the set value updating process when the supply of the operating power to the pachinko machine 10 is started, the operation to the pachinko machine 10 is performed in the situation where the game ball is detected by the gate detection sensor 49a. The configuration may be such that the condition that power supply has started is set. Accordingly, in order to execute the set value updating process when the supply of the operating power to the pachinko machine 10 is started, not only the setting key is inserted into the setting key inserting section 68a and the ON operation is performed, but also the through operation is performed. It becomes necessary to start the supply of operating power to the pachinko machine 10 with the game balls retained in the gate 35. Therefore, it becomes possible to make it difficult to perform an act of illegally changing the set value.

Further, the content of the operation for confirming the set value in the set value update processing may be different from that of the above-described embodiment. FIG. 90 is a flow chart showing a setting value updating process which is another form. In the set value update processing, the same processing as step S5101 to step S5102 and step S5104 to step S5114 of the set value update processing (FIG. 85) in the above embodiment is executed in step S5601 to step S5602 and step S5604 to step S5614. .. On the other hand, in the setting value updating process, in step S5603, the ON signal is continuously output from the gate detection sensor 49a, instead of determining whether or not the game ball is detected by the out-mouth detection sensor 48a. It is determined whether the ON duration is equal to or longer than the termination reference period (specifically, 5 seconds). Then, when an affirmative determination is made in step S5603, the set value being selected is confirmed, and the flow proceeds to step S5609. According to this configuration, it is necessary to intentionally retain the game ball in the through gate 35 for at least the termination reference period in order to confirm the selected setting value. The game ball staying in the through gate 35 for more than the end reference period does not occur in a normal game. This makes it possible to make the condition for confirming the selected setting value not satisfied or difficult to be satisfied in a situation where a normal game is being played. Further, even if the setting value updating process is started due to injustice, it is possible to make it difficult to perform the operation for confirming the setting value being selected in the setting value updating process.

In the set value updating process, the set value being selected may be determined when the operation handle of the firing operation device 28 is rotated from the initial rotation position, and the firing operation device 28 is touched by the player. The configuration may be such that the setting value being selected is confirmed when the setting is performed.

Further, in the set value updating process, the set value being selected may be fixed when the special ball detection sensor 45a detects that the game ball has entered the special electric prize winning device 32 provided with the opening/closing member. It is also possible to adopt a configuration in which the setting value being selected is confirmed when the second operation opening detection sensor 47a detects that the game ball has entered the second operation opening 34 provided with the opening/closing member. In this case, in order to confirm the set value being selected, it is necessary to manually maintain the game ball after opening the target ball entry portion manually, making it difficult to illegally change the set value. It becomes possible.

In addition, in the set value update process, selection is made based on the fact that the game ball has been detected in the second ball entering portion after it has been detected that the game ball has entered the first ball entering portion. It is also possible to adopt a configuration in which the set value inside is fixed. In this case, in order to confirm the set value being selected, it is necessary to enter the game ball into the multiple ball entry parts by maintenance in a predetermined order, so it is difficult to illegally change the set value. Is possible. In this case, the workability of the regular work is not extremely deteriorated by making the first ball entry part and the second ball entry part both ball entry parts not provided with the opening/closing member. It becomes possible to do.

Further, in the setting value updating process, the setting key inserting section 68a may be switched from the ON state to the OFF state to confirm the setting value being selected and satisfy the ending condition of the setting value updating process.

Further, the operation for updating the set value by one step in the set value update processing is not limited to the configuration in which the update button 68b is pressed, and the set value is changed by one step by pressing the reset button 68c. The configuration may be updated.

Further, when the supply of operating power to the pachinko machine 10 is started in a situation where the reset button 68c is pressed and the setting key insertion portion 68a is turned on by the setting key, When the front door frame 14 is not open to the frame 13 or the gaming machine main body 12 is not open to the outer frame 11, a clear process (step S5007) at the time of non-setting update is executed. The configuration is not limited, and the clear process at the time of non-setting update may not be executed. This makes it possible to prevent the clear processing at the time of non-setting update from being executed against the intention of the game hall manager.

In addition, in a case where the reset button 68c is being pressed and the setting key insertion portion 68a is not being turned on by the setting key, the supply of operating power to the pachinko machine 10 is started. If the front door frame 14 is not open to the frame 13 or the gaming machine main body 12 is not open to the outer frame 11, a clear process at the time of non-setting update (step S5007) is executed. The configuration is not limited, and the configuration may be such that the clear processing at the time of non-setting update is not executed. As a result, it is possible to make it difficult to execute the clear process at the time of non-setting update illegally.

<Twenty-third embodiment>
In this embodiment, the processing configuration of the main processing is different from that of the 22nd embodiment. The configuration different from that of the 22nd embodiment will be described below. The description of the same configuration as the twenty-second embodiment is basically omitted.

FIG. 91 is a flowchart showing the main processing executed in the main CPU 63 in this embodiment. The processes of steps S5701 to S5720 in the main process are executed in the main CPU 63 using the specific control program and the specific control data.

First, power-on wait processing is executed (step S5701). In the power-on wait process, for example, the main process is started and waits for a predetermined time for waiting (specifically, 1 second) without proceeding to the next process. During the execution period of the power-on weight process, the operation start and initial setting of the symbol display device 41 are completed. After that, access to the main RAM 65 is permitted (step S5702).

Thereafter, based on the detection result of the front door opening sensor 95, it is determined whether or not the front door frame 14 is open with respect to the inner frame 13 (step S5703), and based on the detection result of the main body opening sensor 96, the outer frame 11 In contrast, it is determined whether or not the gaming machine main body 12 is in the open state (step S5704), and it is determined whether or not the reset button 68c is pressed (step S5705). When a negative determination is made in any of steps S5703 to S5705, the processes of steps S5706 to S5714 are executed. The processing of these steps S5706 to S5714 is the same as the processing of steps S5008 to S5016 of the main processing (FIG. 84) in the twenty-second embodiment.

When a positive determination is made in all of steps S5703 to S5705, selection processing is executed (step S5715). In the selection process, whichever of the following situations is performed, the clear process at the time of non-setting update is executed and the set value update process is not executed, or the clear process at the time of setting update is executed and the set value update process is executed. A process of deciding whether to be based on the selection operation by the manager of the game hall is executed. Specifically, every time the update button 68b is pressed once, the state in which one of the above situations is selected is switched to the state in which the other situation is selected. The selection operation may be performed by operating the reset button 68c, or may be performed by operating another operation unit. Further, when the state where the clear process at the time of non-setting update is executed and the setting value update process is not executed is selected, “O” is displayed on the first notification display device 69a and the second notification display device 69b is displayed. When the state in which the third notification display device 69c is turned off and the setting update process is executed and the setting value update process is executed is selected, “O” is displayed on the second notification display device 69b. Is displayed and the first notification display device 69a and the third notification display device 69c are turned off. In addition, when the reset button 68c is continuously pressed for a fixed selection period (specifically, 10 seconds) or more, the status of the selected side among the above statuses is fixed as the selection target this time. To do.

In addition, when the update button 68b is continuously pressed for a fixed selection period (specifically, 10 seconds) or more, the status of the selected side among the above statuses is fixed as the current selection target. The configuration may be adopted, and when the other operation unit is continuously pressed for a fixed selection period (specifically, 10 seconds) or more, the situation of the selected side among the above situations is selected this time. It may be configured to be determined as a target. Alternatively, the operation handle of the firing operation device 28 may be rotationally operated to determine the selected situation among the above situations as the current selection target.

In the selection process, when the situation where the clear process at the time of non-setting update is executed and the setting value update process is not executed is confirmed as the current selection target (step S5716: NO), the clear process at the time of non-setting update is executed. (Step S5717). The processing content of the clear processing at the time of non-setting update is the same as step S5007 of the main processing (FIG. 84) in the 22nd embodiment.

In the process for selection, when the situation of executing the clear process at the time of setting update and executing the set value update process is confirmed as the current selection target (step S5716: YES), the set value copy process is executed (step S5716). In step S5718, a clear process at the time of setting update is executed (step S5719), and a set value update process is executed (step S5720). The processing contents of these steps S5718 to S5720 are the same as the steps S5017 to S5019 of the main processing (FIG. 84) in the twenty-second embodiment.

According to the above configuration, even if the setting key insertion unit 68a is not provided, the clear process at the time of non-setting update is executed and the setting value update process is not executed, and the clear process at the time of setting update is executed. At the same time, the game hall manager can select which of the situations in which the setting value updating process is to be executed.

Further, not only when performing the set value updating process but also when performing the clearing process at the time of non-setting updating, the operating power is supplied to the pachinko machine 10 when the reset button 68c is pressed. In addition to starting, it is necessary to open the front door frame 14 with respect to the inner frame 13 and open the gaming machine main body 12 with respect to the outer frame 11. As a result, it is possible to make it difficult to execute the clear process at the time of non-setting update illegally.

In addition, as conditions for executing the selection process when the supply of the operating power to the pachinko machine 10 is started, the front door frame 14 is in an open state with respect to the inner frame 13 and the outer frame. Although both the conditions that the gaming machine main body 12 is in the open state are set for 11, the configuration may be such that only one of these conditions is set.

Further, a condition that the firing handle of the firing operation device 28 is rotated is added as a condition for executing the selection process when the supply of the operating power to the pachinko machine 10 is started. As the configuration, the condition that the firing operation device 28 is touched may be added, and the condition that the game ball is detected by the gate detection sensor 49a may be added. Good.

<Twenty-fourth Embodiment>
In this embodiment, the processing configuration of the RAM monitoring processing is different from that of the 22nd embodiment. The configuration different from that of the 22nd embodiment will be described below. The description of the same configuration as the twenty-second embodiment is basically omitted.

FIG. 92 is a flowchart showing the RAM monitoring process executed by the main CPU 63 in this embodiment. The processes of steps S5801 to S5814 in the RAM monitoring process are executed by the main CPU 63 using the specific control program and the specific control data.

First, the monitoring processing of the work area 221 for specific control is executed (step S5801). The contents of the monitoring process are the same as step S5401 of the RAM monitoring process (FIG. 88) in the twenty-second embodiment. If it is determined that there is an abnormality in step S5801 (step S5802: YES), the processes of steps S5805-S5808 are executed.

If it is not determined that there is an abnormality in step S5801 (step S5802: NO), monitoring processing of the stack area 222 for specific control is executed (step S5803). The content of the monitoring process is the same as step S5403 of the RAM monitoring process (FIG. 88) in the twenty-second embodiment. If it is determined that there is an abnormality in step S5803 (step S5804: YES), the processes of steps S5805-S5808 are executed.

For details of the processing in steps S5805 to S5808, first, a setting value copy processing is executed (step S5805). In the copy processing, information on a setting value counter used to specify the setting value of the pachinko machine 10 in the specific control work area 221 is stored in a copy area provided in the specific control work area 221. .. As a result, even if the setting value counter information is cleared to "0" in the abnormal clearing process (step S5806) executed thereafter, the pachinko machine 10 before the abnormal clearing process is executed. It becomes possible to grasp the set value of.

After that, the clear processing at the time of abnormality is executed (step S5806). In the clear processing at the time of abnormality, the work area 221 for specific control is cleared to “0” except the copy area, and the stack area 222 for specific control is cleared to “0”. Also, after "0" is cleared, initial setting is performed. On the other hand, the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to "0". That is, in the RAM monitoring process according to the present embodiment, when it is determined that an abnormality has occurred in either the specific control work area 221 or the specific control stack area 222, the specific control is performed excluding the copy area. The work area 221 for clearing is cleared to "0", and the stack area 222 for specific control is cleared to "0". Accordingly, if there is a possibility that some information abnormality has occurred in the work area 221 for specific control or the stack area 222 for specific control, the processing corresponding to the specific control is executed in that state. It is possible to prevent it. Further, even if an information abnormality occurs in the work area 221 for specific control or the stack area 222 for specific control, the work area 223 for non-specific control and the stack area 224 for non-specific control are cleared to “0”. By not doing so, the work area 223 for non-specific control and the stack area 224 for non-specific control are cleared to “0” due to the information abnormality in the work area 221 for specific control or the stack area 222 for specific control. It becomes possible not to.

When the stack area 222 for specific control is cleared to “0”, the information on the return address after the RAM monitoring processing is also erased. Therefore, when the stack area 222 for specific control is cleared to “0”, the process of step S5808 is terminated, and then a specific program is uniquely restored. Specifically, the processing is uniquely returned to the processing of step S5013 in the main processing (FIG. 22). However, the program that uniquely returns is not limited to step S5013, and may be step S5221 in the timer interrupt processing (FIG. 86). Further, when the stack area 222 for specific control is cleared to “0”, the stack pointer of the main CPU 63 is also set to the address of the first storage area in the storage order in the stack area 222 for specific control.

After that, an abnormal command indicating that the clear processing at the time of abnormality has occurred is transmitted to the sound emission control device 81 (step S5807). Upon receiving the abnormal command, the voice emission control device 81 causes the display light emitting unit 53 to emit light in a mode corresponding to the forced clear, and causes the speaker unit 54 to output the voice “Forced clear.”. In addition, the character image "Forced clear." is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are ended when the supply of operating power to the pachinko machine 10 is stopped. However, the present invention is not limited to this, and the notification may be ended when the notification end operation is performed by the game hall manager. As the notification end operation, for example, the update button 68b may be pressed or the reset button 68c may be pressed. By confirming the above notification, the game hall manager can grasp that the work area 221 for specific control and the stack area 222 for specific control have been forcibly cleared.

After that, the setting value update processing is executed (step S5808). The processing contents of the setting value update processing are the same as step S5412 in the RAM monitoring processing (FIG. 88) in the twenty-second embodiment.

If it is not determined that there is an abnormality in both step S5801 and step S5803 (step S5802 and step S5804: NO), the monitoring process of the work area 223 for non-specific control is executed (step S5809). The contents of the monitoring process are the same as step S5405 of the RAM monitoring process (FIG. 88) in the twenty-second embodiment. When it is determined that there is an abnormality in step S5809 (step S5810: YES), the work area 223 for non-specific control is cleared to “0” and the initial setting is performed (step S5811). In this case, all of the normal counter area 231, the open/close execution mode counter area 232, the high frequency support mode counter area 233, the calculation result storage area 234, and the management start flag are cleared to “0”. This makes it possible to eliminate the information abnormality in the work area 223 for non-specific control.

On the other hand, in step S5811, the work area 221, the stack area 222 for specific control, and the stack area 224 for non-specific control are not cleared to "0". As a result, even if the information abnormality occurs in the work area 223 for non-specific control, the work area 221, the stack area 222 for specific control, and the stack area 224 for non-specific control are " It is possible not to clear "0".

In step S5811, the normal counter area 231, the open/close execution mode counter area 232, the high frequency support mode counter area 233, and the calculation result storage area 234 are cleared to "0", but the management start flag is not cleared to "0". It may be configured. In step S5811, the normal counter area 231, the open/close execution mode counter area 232, the high frequency support mode counter area 233, and the management start flag are cleared to “0”, but the operation result storage area 234 is not cleared to “0”. It may be configured. In step S5811, the normal counter area 231, the open/close execution mode counter area 232, and the high frequency support mode counter area 233 are cleared to “0”, but the calculation result storage area 234 and the management start flag are not cleared to “0”. It may be configured.

If a negative determination is made in step S5810 or the processing of step S5811 is executed, the monitoring processing of the stack area 224 for non-specific control is executed (step S5812). The contents of the monitoring process are the same as step S5407 of the RAM monitoring process (FIG. 88) in the twenty-second embodiment. If it is determined that there is an abnormality in step S5812 (step S5813: YES), the stack area 224 for non-specific control is cleared to “0” and initialized (step S5814). This makes it possible to eliminate the information abnormality in the non-specific control stack area 224.

On the other hand, in step S5814, the work area 221 for specific control, the stack area 222 for specific control, and the work area 223 for non-specific control are not cleared to "0". As a result, even if an information abnormality occurs in the stack area 224 for non-specific control, the work area 221 for specific control, the stack area 222 for specific control, and the work area 223 for non-specific control are " It is possible not to clear "0".

According to the above configuration, when it is specified that an abnormality has occurred in either the specific control work area 221 or the specific control stack area 222, the specific control work area 221 is excluded except for the copy area. Is cleared to "0" and the stack area 222 for specific control is cleared to "0". Accordingly, if there is a possibility that some information abnormality has occurred in the work area 221 for specific control or the stack area 222 for specific control, the processing corresponding to the specific control is executed in that state. It is possible to prevent it.

Even if an information abnormality occurs in the specific control work area 221 or the specific control stack area 222, the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to “0”. As a result, the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to "0" by the information abnormality in the work area 221 for specific control or the stack area 222 for specific control. It becomes possible to do so.

Even if an abnormal information occurs in the non-specific control work area 223, the work area 221 for specific control, the stack area 222 for specific control, and the stack area 224 for non-specific control are not cleared to “0”. As a result, the work area 221 for specific control, the stack area 222 for specific control, and the stack area 224 for non-specific control are prevented from being cleared to “0” due to the information abnormality in the work area 223 for non-specific control. It becomes possible.

Even if the information abnormality occurs in the non-specific control stack area 224, the work area 221 for the specific control, the stack area 222 for the specific control, and the work area 223 for the non-specific control are not cleared to “0”. This prevents the work area 221 for specific control, the stack area 222 for specific control, and the work area 223 for non-specific control from being cleared to "0" by the information abnormality in the stack area 224 for non-specific control. It becomes possible.

When an information error occurs in the specific control work area 221, the specific control work area 221 is cleared to “0” except for the copy area, while the specific control stack area 222 is set to “0”. The configuration may not be cleared to "0".

Further, when an information abnormality has occurred in the stack area 222 for specific control, the stack area 222 for specific control is cleared to “0”, while the work area 221 for specific control is not cleared to “0”. May be In this case, even if the stack area 222 for specific control is cleared to “0”, the processing in steps S5805 to S5808 may not be executed.

<Twenty-fifth embodiment>
In this embodiment, the processing configuration for monitoring whether or not an information abnormality has occurred in each of the areas 221 to 224 of the main RAM 65 is different from that of the 22nd embodiment. The configuration different from that of the 22nd embodiment will be described below. The description of the same configuration as the twenty-second embodiment is basically omitted.

FIG. 93 is a flowchart showing the RAM monitoring process executed by the main CPU 63 in this embodiment. The processes of steps S5901 to S5908 in the RAM monitoring process are executed by the main CPU 63 using the specific control program and the specific control data.

First, the monitoring processing of the work area 221 for specific control is executed (step S5901). The contents of the monitoring process are the same as step S5401 of the RAM monitoring process (FIG. 88) in the twenty-second embodiment. If it is determined that there is an abnormality in step S5901 (step S5902: YES), the processes of steps S5905-S5908 are executed.

If it is not determined that there is an abnormality in step S5901 (step S5902: NO), monitoring processing of the stack area 222 for specific control is executed (step S5903). The content of the monitoring process is the same as step S5403 of the RAM monitoring process (FIG. 88) in the twenty-second embodiment. If it is determined that there is an abnormality in step S5903 (step S5904: YES), the processes of steps S5905-S5908 are executed.

For details of the processing in steps S5905 to S5908, first, a setting value copy processing is executed (step S5905). In the copy processing, information on a setting value counter used to specify the setting value of the pachinko machine 10 in the specific control work area 221 is stored in a copy area provided in the specific control work area 221. .. As a result, even if the set value counter information is cleared to “0” in the abnormal clearing process (step S5906) executed thereafter, the pachinko machine 10 before the abnormal clearing process is executed. It becomes possible to grasp the set value of.

After that, the clear processing at the time of abnormality is executed (step S5906). In the clear processing at the time of abnormality, the work area 221 for specific control is cleared to “0” except the copy area, and the stack area 222 for specific control is cleared to “0”. Also, after "0" is cleared, initial setting is performed. On the other hand, the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to "0". That is, in the RAM monitoring process according to the present embodiment, when it is determined that an abnormality has occurred in either the specific control work area 221 or the specific control stack area 222, the specific control is performed excluding the copy area. The work area 221 for clearing is cleared to "0", and the stack area 222 for specific control is cleared to "0". Accordingly, if there is a possibility that some information abnormality has occurred in the work area 221 for specific control or the stack area 222 for specific control, the processing corresponding to the specific control is executed in that state. It is possible to prevent it. Further, even if an information abnormality occurs in the work area 221 for specific control or the stack area 222 for specific control, the work area 223 for non-specific control and the stack area 224 for non-specific control are cleared to “0”. By not doing so, the work area 223 for non-specific control and the stack area 224 for non-specific control are cleared to “0” due to the information abnormality in the work area 221 for specific control or the stack area 222 for specific control. It becomes possible not to.

After that, an abnormal command indicating that the clear processing at the abnormal time has occurred is transmitted to the voice emission control device 81 (step S5907). Upon receiving the abnormal command, the sound emission control device 81 causes the display light emitting unit 53 to emit light in a mode corresponding to the forced clearing of the specific control work area 221 and the specific control stack area 222, and the speaker unit 54. To output the sound "Forced clear has been executed for specific control." In addition, the character image "Forced clear has been executed for specific control." is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are ended when the supply of operating power to the pachinko machine 10 is stopped. However, the present invention is not limited to this, and the notification may be ended when the notification end operation is performed by the game hall manager. As the notification end operation, for example, the update button 68b may be pressed or the reset button 68c may be pressed. By confirming the above notification, the game hall manager can grasp that the work area 221 for specific control and the stack area 222 for specific control have been forcibly cleared.

After that, the setting value update processing is executed (step S5908). The processing contents of the setting value update processing are the same as step S5412 in the RAM monitoring processing (FIG. 88) in the twenty-second embodiment.

As described above, in the RAM monitoring process executed by using the specific control program and the specific control data, information abnormality is monitored in the specific control work area 221 and the specific control stack area 222. However, the abnormal information is not monitored for the work area 223 for non-specific control and the stack area 224 for non-specific control. The monitoring of the information abnormality of the work area 223 for non-specific control and the stack area 224 for non-specific control is performed in a process corresponding to the non-specific control in which the non-specific control program and the non-specific control data are used. Is executed.

FIG. 94 is a flowchart showing the management execution process executed by the main CPU 63 in this embodiment. Note that the management execution process is executed by reading the program of the subroutine in the management process (FIG. 70) as in the fifteenth embodiment. Further, the processes of steps S6001 to S6016 in the management execution process are executed by the main CPU 63 using the non-specific control program and the non-specific control data.

In steps S6001 to S6008 and steps S6010 to S6016, the same processes as steps S3901 to S3915 of the management execution process (FIG. 71) in the fifteenth embodiment are executed. Further, in step S6009, another monitoring process is executed. When the separate monitoring process is executed, the subroutine program corresponding to the separate monitoring process set in the non-specific control program is executed. However, when executing the subroutine program, the separate monitoring process is executed. Information for specifying the return address of the later management execution processing is written in the stack area 224 for non-specific control by the push command. Then, when the separate monitoring process is completed, the information for specifying the return address is read by the pop command, and the process returns to the program of the management execution process indicated by the return address.

FIG. 95 is a flowchart showing another monitoring process. The processes of steps S6101 to S6108 in the separate monitoring process are executed by the main CPU 63 using the non-specific control program and the non-specific control data.

First, the monitoring process of the work area 223 for non-specific control is executed (step S6101). The contents of the monitoring process are the same as step S5405 of the RAM monitoring process (FIG. 88) in the twenty-second embodiment. When it is determined that there is an abnormality in step S6101 (step S6102: YES), the work area 223 for non-specific control is cleared to "0" and the initial setting is performed (step S6103). In this case, all of the normal counter area 231, the open/close execution mode counter area 232, the high frequency support mode counter area 233, the calculation result storage area 234, and the management start flag are cleared to “0”. This makes it possible to eliminate the information abnormality in the work area 223 for non-specific control.

On the other hand, in step S6103, the work area 221, the stack area 222 for specific control, and the stack area 224 for non-specific control are not cleared to "0". As a result, even if the information abnormality occurs in the work area 223 for non-specific control, the work area 221, the stack area 222 for specific control, and the stack area 224 for non-specific control are " It is possible not to clear "0".

In step S6103, the normal counter area 231, the open/close execution mode counter area 232, the high-frequency support mode counter area 233, and the calculation result storage area 234 are cleared to "0", but the management start flag is not cleared to "0". It may be configured. In step S6103, the normal counter area 231, the open/close execution mode counter area 232, the high-frequency support mode counter area 233, and the management start flag are cleared to "0", but the operation result storage area 234 is not cleared to "0". It may be configured. In step S6103, the normal counter area 231, the open/close execution mode counter area 232, and the high frequency support mode counter area 233 are cleared to "0", but the operation result storage area 234 and the management start flag are not cleared to "0". It may be configured.

After that, a clear notification process is executed (step S6104). In the clear notification process, a command indicating that the work area 223 for non-specific control has been cleared to “0” is transmitted to the sound emission control device 81. Upon receiving the command, the sound emission control device 81 causes the display light emitting unit 53 to emit light in a mode corresponding to the forcible clearing of the work area 223 for non-specific control, and the history information is forcibly cleared from the speaker unit 54. The voice is output. Further, the character image "History information has been forcibly cleared." is displayed on the pattern display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are ended when the supply of operating power to the pachinko machine 10 is stopped. However, the present invention is not limited to this, and the notification may be ended when the notification end operation is performed by the game hall manager. As the notification end operation, for example, the update button 68b may be pressed or the reset button 68c may be pressed. By confirming the notification, the game hall manager can grasp that the work area 223 for non-specific control has been forcibly cleared.

When a negative determination is made in step S6102 or the processing of step S6104 is executed, the monitoring processing of the stack area 224 for non-specific control is executed (step S6105). The contents of the monitoring process are the same as step S5407 of the RAM monitoring process (FIG. 88) in the twenty-second embodiment. When it is determined that there is an abnormality in step S6105 (step S6106: YES), the stack area 224 for non-specific control is cleared to "0" and the initial setting is performed (step S6107). This makes it possible to eliminate the information abnormality in the non-specific control stack area 224.

On the other hand, in step S6107, the work area 221 for specific control, the stack area 222 for specific control, and the work area 223 for non-specific control are not cleared to "0". As a result, even if an information abnormality occurs in the stack area 224 for non-specific control, the work area 221 for specific control, the stack area 222 for specific control, and the work area 223 for non-specific control are " It is possible not to clear "0".

After that, a clear notification process is executed (step S6108). In the clear notification process, a command indicating that the stack area 224 for non-specific control has been cleared to “0” is transmitted to the sound emission control device 81. Upon receiving the command, the sound emission control device 81 causes the display light emitting unit 53 to emit light in a mode corresponding to the forcible clearing of the stack area 224 for non-specific control, and causes the speaker unit 54 to display "the stack for non-specific control is It was forcibly cleared." is output. In addition, the character image "The stack of non-specific control has been forcibly cleared." is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are ended when the supply of operating power to the pachinko machine 10 is stopped. However, the present invention is not limited to this, and the notification may be ended when the notification end operation is performed by the game hall manager. As the notification end operation, for example, the update button 68b may be pressed or the reset button 68c may be pressed. By confirming the notification, the game hall manager can grasp that the stack area 224 for non-specific control has been forcibly cleared.

When the stack area 224 for non-specific control is forcibly cleared, the program address of step S6010 in the management execution process (FIG. 94) is uniquely set as the information of the return address after the execution of the separate monitoring process. .. As a result, even if the stack area 224 for non-specific control is forcibly cleared, it is possible to return to the program that should be restored in the management execution process. Further, when the stack area 224 for non-specific control is forcibly cleared, the stack pointer of the main CPU 63 is also set to the address of the first storage area in the storage order in the stack area 224 for non-specific control.

According to the above configuration, monitoring whether or not an information abnormality has occurred in the work area 221 for specific control and the stack area 222 for specific control is executed in the process corresponding to the specific control in the main CPU 63, and Monitoring of whether or not an information abnormality has occurred in the work area 223 for specific control and the stack area 224 for non-specific control is executed in a process corresponding to the non-specific control in the main CPU 63. This not only clearly distinguishes the areas 221 to 224 of the main RAM 65 to be used by the processing corresponding to the specific control and the processing corresponding to the non-specific control, but also the area of the main RAM 65 to be monitored. It is also possible to clearly distinguish 221 to 224.

When the work area 223 for non-specific control is cleared to “0”, it is information of various registers of the main CPU 63 used in the process corresponding to the specific control and is stored in the work area 223 for non-specific control. The saved information is also cleared to "0". In this case, even if the process corresponding to the non-specific control ends and returns to the process corresponding to the specific control, it may not be possible to return to the state before the process corresponding to the non-specific control is started. Therefore, when the work area 223 for non-specific control is cleared to “0”, the work area 221 for specific control and the stack area 222 for specific control may be cleared to “0”. Further, in the configuration, the setting value counter in the work area 221 for specific control is also cleared to “0”, and therefore, when the process corresponding to the non-specific control is returned to the process corresponding to the specific control, the specific control is performed. The setting value update process may be executed first as the corresponding process.

<Twenty-sixth Embodiment>
In this embodiment, the processing configuration of the management process is different from that in the twentieth embodiment. The configuration different from that of the twentieth embodiment will be described below. The description of the same configuration as that of the twentieth embodiment is basically omitted.

FIG. 96 is a flowchart showing the management processing executed by the main CPU 63 in this embodiment. The processes of steps S6201 to S6219 in the management process are executed by the main CPU 63 using the specific control program and the specific control data.

First, in order to prohibit the occurrence of the timer interrupt process (FIG. 69), interrupt prohibition is set (step S6201). This prevents the timer interrupt process (FIG. 69), which is a process corresponding to the specific control, from being interrupted and activated in the middle of a management execution process, which will be described later, which is a process corresponding to the non-specific control. Is possible.

After that, the information of the stack pointer of the main CPU 63 is overwritten in the HL register of the main CPU 63 by the load instruction as "LD HL,SP" (step S6202). In this case, since the amount of information of the stack pointer is 16 bits and the amount of information of each of the H register and the L register is 8 bits, information of 8 bits consecutive from the upper side of the stack pointer is H register. , And 8-bit information consecutive from the lower side of the stack pointer is overwritten on the L register.

After that, as "LD (HL), 0", the 1-byte storage area corresponding to the information of the stack pointer stored in the HL register of the main CPU 63 in the stack area 222 for specific control is set to "0" by the load instruction. It is cleared (step S6203). The information of the stack pointer of the main CPU 63 is overwritten in the HL register of the main CPU 63 in step S6202, and the stack pointer of the main CPU 63 is not updated until the processing of step S6203 is executed. Since it has not been performed, in step S6203, the 1-byte storage area corresponding to the stack pointer information of the main CPU 63 in the stack area 222 for specific control is cleared to "0".

After that, as "LDSP, SP-1," the load instruction updates the information of the stack pointer of the main CPU 63 to the information of the address of the storage area to be written next in the stack area 222 for specific control. (Step S6204). When the stack area 222 for specific control is used, the information to be stored is stored from the storage area of the last address in the stack area 222 for specific control, and is added each time the information to be stored is added. The storage area of the storage destination is changed toward the first address side in the stack area 222. Therefore, in step S6204, the information of the stack pointer of the main CPU 63 is updated to the information of the address corresponding to the storage area on the side where the address is smaller by one in the stack area 222 for specific control. By executing the processing of step S6204, the storage area of the next order is set as the storage object of the information by the next push command with respect to the storage area cleared to “0” in step S6203, and in step S6203. The storage area cleared to “0” is set as a target for reading information by the next pop command.

After that, as "LD WA, 0", the WA register of the main CPU 63 is cleared to "0" by a load instruction (step S6205). Also, as "LD BC,0", the BC register of the main CPU 63 is cleared to "0" by a load instruction (step S6206). Further, as "LD DE,0", the DE register of the main CPU 63 is cleared to "0" by a load instruction (step S6207). Also, as "LD HL,0", the HL register of the main CPU 63 is cleared to "0" by a load instruction (step S6208). Further, as "LD IX,0", the IX register of the main CPU 63 is cleared to "0" by the load instruction (step S6209). Further, as "LD IY,0", the IY register of the main CPU 63 is cleared to "0" by a load instruction (step S6210).

In addition to the flag register, various registers of the main CPU 63 include various general-purpose registers, auxiliary registers, and index registers. In this case, in steps S6205 to S6210, the WA register, the BC register, the DE register, the HL register, the IX register, and the IY register, which are some of these various general-purpose registers, auxiliary registers, and index registers, are set. Clear "0". The WA register, BC register, DE register, HL register, IX register, and IY register are registers used in the management execution process (step S6212) that is a process corresponding to non-specific control. Before the process corresponding to the non-specific control is started, the states of these registers are cleared by clearing "0" to the management execution process (step S6212) which is a process corresponding to the non-specific control. In addition, it is possible to set the state immediately after the supply of the operating power to the main CPU 63 is started.

In addition, each information of the WA register, BC register, DE register, HL register, IX register, and IY register before the process corresponding to the non-specific control starts after the process corresponding to the non-specific control ends. This is unnecessary information in the process corresponding to the specific control. Therefore, even if the information in these registers is cleared to "0" without being saved, no problem occurs in the processing corresponding to the specific control that is restored after the processing corresponding to the non-specific control ends.

After that, as a “POP PSW”, a pop instruction is used to read information from the storage area in the writing order one before the storage area corresponding to the information of the stack pointer of the main CPU 63 in the stack area 222 for specific control, The read information is overwritten in the flag register of the main CPU 63 (step S6211). The information of the stack pointer of the main CPU 63 immediately before the pop instruction is executed in step S6211 is the storage area of the next write order with respect to the storage area in the stack area 222 for specific control which is cleared to “0” in step S6203. It is the information corresponding to. Therefore, the storage area in the write order that is one before the storage area corresponding to the information of the stack pointer of the main CPU 63 in the stack area 222 for specific control is the storage area cleared to “0” in step S6203. .. Then, by overwriting the flag register of the main CPU 63 with the information read from this storage area, the flag register is in a state of being cleared to "0". Note that one storage area in the stack area 222 for specific control has an information amount of 8 bits (1 byte), and the flag register of the main CPU 63 also has an information amount of 8 bits (1 byte). .. By clearing the flag register to "0" prior to the execution of the management execution process (step S6212) which is the process corresponding to the non-specific control, the state of the flag register is set before the process corresponding to the non-specific control is started. The state immediately after the supply of the operating power to the main CPU 63 is started can be achieved.

After that, the management execution process is started by reading the program of the subroutine corresponding to the management execution process set in the non-specific control program (step S6212). In this case, the information for specifying the return address of the management process after the execution of the management execution process is written in the stack area 222 for specific control by the push command. Then, when the management execution processing is completed, the information for specifying the return address is read by the pop command, and the program for the management processing indicated by the return address is returned to.

The contents of the management execution process are the same as the management execution process (FIG. 82) in the twentieth embodiment. Therefore, after the check processing is completed in the management execution processing, the WA register, BC register, DE register, HL register, IX register, and IY register are cleared to "0". As a result, these registers are cleared to “0” before returning from the process corresponding to the non-specific control to the process corresponding to the specific control, and the states of these registers are reset before returning to the process corresponding to the specific control. The state immediately after the supply of the operating power to the main CPU 63 is started can be achieved.

After returning to the management processing program after executing the management execution processing, processing for clearing the flag register of the main CPU 63 to "0" is executed. Specifically, first, as "PUSH HL", a push instruction saves the information in the HL register of the main CPU 63 to the stack area 222 for specific control (step S6213). After the execution of the push instruction, the information of the stack pointer of the main CPU 63 is the information corresponding to the storage area in the next writing order with respect to the storage area in which the information of the HL register is saved in the stack area 222 for specific control. Become.

After that, the information of the stack pointer of the main CPU 63 is overwritten in the HL register of the main CPU 63 by a load instruction as "LD HL,SP" (step S6214). In this case, since the amount of information of the stack pointer is 16 bits and the amount of information of each of the H register and the L register is 8 bits, information of 8 bits consecutive from the upper side of the stack pointer is H register. , And 8-bit information consecutive from the lower side of the stack pointer is overwritten on the L register.

After that, as "LD (HL), 0", the 1-byte storage area corresponding to the information of the stack pointer stored in the HL register of the main CPU 63 in the stack area 222 for specific control is set to "0" by the load instruction. Clear (step S6215). The information of the stack pointer of the main CPU 63 is overwritten in the HL register of the main CPU 63 in step S6214, and the stack pointer of the main CPU 63 is not updated until the process of step S6215 is executed. Since it has not been performed, in step S6215, the 1-byte storage area corresponding to the information of the stack pointer of the main CPU 63 in the stack area 222 for specific control is cleared to "0".

After that, as "LDSP, SP-1," the load instruction updates the information of the stack pointer of the main CPU 63 to the information of the address of the storage area to be written next in the stack area 222 for specific control. (Step S6216). When the stack area 222 for specific control is used, the information to be stored is stored from the storage area of the last address in the stack area 222 for specific control, and is added each time the information to be stored is added. The storage area of the storage destination is changed toward the first address side in the stack area 222. Therefore, in step S6216, the information of the stack pointer of the main CPU 63 is updated to the information of the address corresponding to the storage area on the side where the address is smaller by one in the stack area 222 for specific control. By executing the processing of step S6216, the storage area in the next order is set as the storage target of information by the next push command with respect to the storage area cleared to "0" in step S6215, and in step S6215. The storage area cleared to “0” is set as a target for reading information by the next pop command.

After that, as a "POP PSW", a pop instruction is used to read information from the storage area in the write order immediately before the storage area corresponding to the information of the stack pointer of the main CPU 63 in the stack area 222 for specific control, The read information is overwritten in the flag register of the main CPU 63 (step S6217). The information of the stack pointer of the main CPU 63 immediately before the execution of the pop instruction in step S6217 is the storage area of the next writing order with respect to the storage area in the stack area 222 for specific control which is cleared to “0” in step S6215. It is the information corresponding to. Therefore, the storage area in the writing order that is one before the storage area corresponding to the information of the stack pointer of the main CPU 63 in the stack area 222 for specific control is the one for specific control which is cleared to “0” in step S6215. It becomes a storage area in the stack area 222. Then, by overwriting the flag register of the main CPU 63 with the information read from this storage area, the flag register is in a state of being cleared to "0". Note that one storage area in the stack area 222 for specific control has an information amount of 8 bits (1 byte), and the flag register of the main CPU 63 also has an information amount of 8 bits (1 byte). .. By clearing the flag register to “0” after execution of the management execution process (step S6212) which is a process corresponding to the non-specific control, the main CPU 63 is set after the process corresponding to the non-specific control is completed. It is possible to set the state immediately after the supply of the operating power to the device is started. Further, when the pop instruction is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area in which the writing order in the stack area 222 for specific control is one before.

After that, as "POP HL", the information of the HL register saved in the stack area 222 for specific control in step S6213 is restored to the HL register of the main CPU 63 by the pop command (step S6218). Since the HL register is cleared to “0” immediately before the management execution process (step S6212) is completed, the information cleared to “0” is saved to the stack area 222 for specific control in step S6213. At the same time, in step S6218, the information cleared to "0" is returned to the HL register of the main CPU 63, and as a result, the HL register of the main CPU 63 is cleared to "0". When the pop instruction is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area in which the writing order in the stack area 222 for specific control is two before.

After that, in order to switch from the state in which the generation of the timer interrupt processing (FIG. 69) is prohibited to the state in which the timer interrupt processing is permitted, the interrupt permission is set (step S6219). This enables a new execution of the timer interrupt process.

According to the above structure, the following effects can be obtained in addition to the effects described in the twentieth embodiment.

The configuration is such that the flag register of the main CPU 63 is cleared to "0" when the process corresponding to the non-specific control is started from the situation where the process corresponding to the specific control is being executed. This eliminates the need to save the information of the flag register used in the process corresponding to the specific control in the main RAM 65 in the situation where the process corresponding to the non-specific control is executed. Therefore, there is no need to secure a capacity for saving the information.

Also, the flag register of the main CPU 63 is cleared to "0" even when the process corresponding to the non-specific control is returned to the process corresponding to the specific control. As a result, when returning to the process corresponding to the specific control, it becomes possible to return the state of the flag register to the state immediately before the start of the process corresponding to the non-specific control.

The state in which the flag register is cleared to "0" is the state when the supply of operating power to the main CPU 63 is started. This makes it possible to simplify the processing configuration for setting the flag register to the predetermined state when starting the process corresponding to the non-specific control and when returning to the process corresponding to the specific control.

The information in the flag register of the main CPU 63 before the processing corresponding to the non-specific control is information that is not used in the processing corresponding to the specific control after the processing corresponding to the non-specific control ends. As a result, even if the flag register is cleared to “0” when the process corresponding to the non-specific control is started, the process corresponding to the specific control after the process corresponding to the non-specific control is finished. It becomes possible not to affect.

A predetermined storage area of the stack area 222 for specific control is cleared to "0", and the flag register is cleared to "0" by overwriting the flag register with the information of the cleared "0" storage area. The composition. This makes it possible to clear the flag register to "0" even if the flag register is restricted from being directly cleared to "0" by a load instruction.

The flag register may be initialized instead of clearing the flag register to "0". That is, when the supply of the operating power to the main CPU 63 is started, the flag register of the main CPU 63 is temporarily cleared to "0" and then the information is set to the initial state. In S6204 and S6211, the flag register may be set so as to be in this initial state. In this case, the flag register is set so as to be in the initial state also in steps S6213 to S6218, so that the state of the flag register is set to the non-specific control when returning to the process corresponding to the specific control. It is possible to return to the state immediately before the process corresponding to is started.

Further, in steps S6202 to S6204 and step S6211, instead of the configuration in which the flag registers of the main CPU 63 are cleared to "0", "1" may be set in all the flag registers. In this case, by setting "1" in all of the flag registers also in steps S6213 to S6218, when returning to the process corresponding to the specific control, the state of the flag register starts the process corresponding to the non-specific control. It is possible to return to the state immediately before the operation.

Further, instead of the processing of steps S6202 to S6204 and step S6211, "LD PSW,0" may be configured to directly clear the flag register of the main CPU 63 by "0" by a load instruction. Further, instead of the processes of steps S6213 to S6218, the flag register of the main CPU 63 may be directly cleared to "0" by a load instruction as "LD PSW,0".

Further, instead of the configuration of executing the processing of step S6213 and step S6218, the configuration may be such that "LD HL,0" clears the HL register by "0" by a load instruction. Even in this case, the state of the HL register can be returned to the state immediately before the management execution process, which is a process corresponding to the non-specific control, is executed.

Further, instead of the configuration in which the process of clearing the flag register to “0” is executed in the process corresponding to the specific control, the process may be executed in the process corresponding to the non-specific control.

<Twenty-seventh embodiment>
In this embodiment, the processing configuration of the management process is different from that in the twentieth embodiment. The configuration different from that of the twentieth embodiment will be described below. The description of the same configuration as that of the twentieth embodiment is basically omitted.

FIG. 97 is a flowchart showing the management process executed by the main CPU 63 in this embodiment. The processes of steps S6301 to S6233 in the management process are executed by the main CPU 63 using the specific control program and the specific control data.

First, in order to prohibit the occurrence of the timer interrupt process (FIG. 69), interrupt prohibition is set (step S6301). This prevents the timer interrupt process (FIG. 69), which is a process corresponding to the specific control, from being interrupted and activated in the middle of a management execution process, which will be described later, which is a process corresponding to the non-specific control. Is possible.

After that, as "PUSH AF", a push instruction stores each of the information of the A register of the main CPU 63 and the information of the flag register corresponding to the current stack pointer information of the main CPU 63 in the stack area 222 for specific control. The area and the storage area in the next writing order are saved in the storage area (step S6302). Since the A register and the flag register of the main CPU 63 each have an information amount of 8 bits (1 byte), the information of the A register and the information of the flag register are individually stored in two storage areas having consecutive addresses. Evacuated. When the push command is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area two in the writing order in the stack area 222 for specific control.

Thereafter, as "POP HL", a pop instruction overwrites the HL register of the main CPU 63 with the information of the A register and the information of the flag register saved in the stack area 222 for specific control in step S6302 (step S6303). .. In this case, the information of the A register saved in the stack area 222 for specific control is overwritten in the H register of the main CPU 63, and the information of the flag register saved in the stack area 222 for specific control is L of the main CPU 63. Register is overwritten. The H register and the L register of the main CPU 63 each have an information amount of 8 bits (1 byte). When the pop instruction is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area in which the write order in the stack area 222 for specific control is two before.

After that, as "LD A,0", the A register of the main CPU 63 is cleared to "0" by a load instruction (step S6304). Then, as "LDL, A", the load instruction overwrites the information in the A register of the main CPU 63 in the L register of the main CPU 63 (step S6305), and at the same time as "LD H, A", by the load instruction. The information in the A register of the main CPU 63 is overwritten in the H register of the main CPU 63 (step S6306). Since the A register is cleared to "0" in step S6304, the L register and the H register are overwritten with the information of the A register to clear the L register and the H register to "0". Becomes

After that, as “PUSH HL”, the push instruction causes the information of the HL register (that is, the H register and the L register) of the main CPU 63 to correspond to the information of the current stack pointer of the main CPU 63 in the stack area 222 for specific control. The storage area and the storage area in the next writing order with respect to the storage area are saved (step S6307). Since the H register and the L register of the main CPU 63 each have an information amount of 8 bits (1 byte), the information of the H register and the information of the L register are individually stored in two storage areas having consecutive addresses. Evacuated. When the push command is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area two in the writing order in the stack area 222 for specific control.

After that, as "LD BC, 0", the BC register of the main CPU 63 is cleared to "0" by a load instruction (step S6308). Further, as "LD DE,0", the DE register of the main CPU 63 is cleared to "0" by a load instruction (step S6309). Also, as "LD IX,0", the IX register of the main CPU 63 is cleared to "0" by a load instruction (step S6310). Further, as "LD IY,0", the IY register of the main CPU 63 is cleared to "0" by a load instruction (step S6311).

In addition to the flag register, various registers of the main CPU 63 include various general-purpose registers, auxiliary registers, and index registers. In this case, in steps S6308 to S6311, the BC register, the DE register, the IX register, and the IY register, which are some of the various general-purpose registers, auxiliary registers, and index registers, are cleared to "0". Also, the HL register is cleared to "0" in steps S6305 and S6306. These BC register, DE register, HL register, IX register, and IY register are registers used in the management execution process (step S6313) which is a process corresponding to non-specific control. Before the processing corresponding to the non-specific control is started, the states of these registers are cleared by clearing "0" to the management execution processing (step S6313) which is the processing corresponding to the non-specific control. In addition, it is possible to set the state immediately after the supply of the operating power to the main CPU 63 is started.

Further, each information of the BC register, the DE register, the HL register, the IX register, and the IY register before the processing corresponding to the non-specific control is changed to the specific control after the processing corresponding to the non-specific control is finished. This is unnecessary information in the corresponding processing. Therefore, even if the information in these registers is cleared to "0" without being saved, no problem occurs in the processing corresponding to the specific control that is restored after the processing corresponding to the non-specific control ends.

After that, as "POP AF", by a pop instruction, the information of the H register and the information of the L register saved in the stack area 222 for specific control in step S6307 are overwritten in the A register and the flag register of the main CPU 63 ( Step S6312). In this case, the information of the H register saved in the stack area 222 for specific control is overwritten in the A register of the main CPU 63, and the information of the L register saved in the stack area 222 for specific control is flagged by the main CPU 63. Register is overwritten. Since the information of the H register and the information of the L register saved in the stack area 222 for specific control are all “0” information, the A register of the main CPU 63 is changed to the A register by executing the process of step S6312. The state is cleared to "0" and the flag register of the main CPU 63 is also cleared to "0". As a result, the state of the flag register can be set to the state immediately after the supply of the operating power to the main CPU 63 is started before the processing corresponding to the non-specific control is started. When the pop instruction is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area in which the write order in the stack area 222 for specific control is two before.

After that, the management execution process is started by reading the program of the subroutine corresponding to the management execution process set in the non-specific control program (step S6313). In this case, the information for specifying the return address of the management process after the execution of the management execution process is written in the stack area 222 for specific control by the push command. Then, when the management execution processing is completed, the information for specifying the return address is read by the pop command, and the program for the management processing indicated by the return address is returned to.

Note that after the check processing is completed in the management execution processing, the BC register, the DE register, the HL register, the IX register, and the IY register are cleared to "0". As a result, these registers are cleared to “0” before returning from the process corresponding to the non-specific control to the process corresponding to the specific control, and the states of these registers are reset before returning to the process corresponding to the specific control. The state immediately after the supply of the operating power to the main CPU 63 is started can be achieved.

After returning to the management processing program after executing the management execution processing, processing for clearing the flag register of the main CPU 63 to "0" is executed. Specifically, first, as "PUSH HL", a push instruction saves the information in the HL register of the main CPU 63 to the stack area 222 for specific control (step S6314). After the execution of the push instruction, the information of the stack pointer of the main CPU 63 is the information corresponding to the storage area in the next writing order with respect to the storage area in which the information of the HL register is saved in the stack area 222 for specific control. Become.

Then, as "PUSH AF", a push instruction stores each of the information of the A register of the main CPU 63 and the information of the flag register corresponding to the information of the current stack pointer of the main CPU 63 in the stack area 222 for specific control. The storage area and the storage area in the next writing order are saved to the storage area (step S6315). Since the A register and the flag register of the main CPU 63 each have an information amount of 8 bits (1 byte), the information of the A register and the information of the flag register are individually stored in two storage areas having consecutive addresses. Evacuated. When the push command is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area two in the writing order in the stack area 222 for specific control.

After that, as "POP HL", the pop instruction overwrites the HL register of the main CPU 63 with the information of the A register and the information of the flag register saved in the stack area 222 for specific control in step S6315 (step S6316). .. In this case, the information of the A register saved in the stack area 222 for specific control is overwritten in the H register of the main CPU 63, and the information of the flag register saved in the stack area 222 for specific control is L of the main CPU 63. Register is overwritten. The H register and the L register of the main CPU 63 each have an information amount of 8 bits (1 byte). When the pop instruction is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area in which the write order in the stack area 222 for specific control is two before.

After that, as “LD A,0”, the A register of the main CPU 63 is cleared to “0” by a load instruction (step S6317). Then, the information of the A register of the main CPU 63 is overwritten in the L register of the main CPU 63 by the load instruction as "LDL, A" (step S6318), and the load instruction by "LD H, A" The information in the A register of the main CPU 63 is overwritten in the H register of the main CPU 63 (step S6319). Since the A register has been cleared to "0" in step S6317, the L register and the H register have been cleared to "0" by overwriting the information of the A register in the L register and the H register, respectively. Becomes

After that, as “PUSH HL”, the push instruction causes the information of the HL register (that is, the H register and the L register) of the main CPU 63 to correspond to the information of the current stack pointer of the main CPU 63 in the stack area 222 for specific control. The storage area and the storage area in the next writing order with respect to the storage area are saved (step S6320). Since the H register and the L register of the main CPU 63 each have an information amount of 8 bits (1 byte), the information of the H register and the information of the L register are individually stored in two storage areas having consecutive addresses. Evacuated. When the push command is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area two in the writing order in the stack area 222 for specific control.

After that, as "POP AF", by a pop command, the information of the H register and the information of the L register saved in the stack area 222 for specific control in step S6320 are overwritten in the A register and the flag register of the main CPU 63 ( Step S6321). In this case, the information of the H register saved in the stack area 222 for specific control is overwritten in the A register of the main CPU 63, and the information of the L register saved in the stack area 222 for specific control is flagged by the main CPU 63. Register is overwritten. Since the information of the H register and the information of the L register saved in the stack area 222 for specific control are all “0” information, the A register of the main CPU 63 is changed to the A register by executing the process of step S6321. The state is cleared to "0" and the flag register of the main CPU 63 is also cleared to "0". By clearing the flag register to "0" after the management execution process (step S6313) which is a process corresponding to the non-specific control, the state of the flag register is terminated after the process corresponding to the non-specific control is completed, and then the main CPU 63 It is possible to set the state immediately after the supply of the operating power to the device is started. When the pop instruction is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area in which the write order in the stack area 222 for specific control is two before.

After that, as "POP HL", the information of the HL register saved in the stack area 222 for specific control in step S6314 is restored to the HL register of the main CPU 63 by the pop command (step S6322). Since the HL register is cleared to “0” immediately before the management execution process (step S6313) ends, in step S6314 the information cleared to “0” is saved in the stack area 222 for specific control. At the same time, in step S6322, the "0"-cleared information is returned to the HL register of the main CPU 63, so that the HL register of the main CPU 63 is eventually cleared to "0". When the pop instruction is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area in which the writing order in the stack area 222 for specific control is two before.

After that, the interrupt permission is set to switch from the state in which the generation of the timer interrupt process (FIG. 69) is prohibited to the state in which the generation is permitted (step S6323). This enables a new execution of the timer interrupt process.

According to the above configuration, the flag register of the main CPU 63 can be cleared to “0” without executing the process of clearing “0” by the load instruction to the predetermined storage area in the stack area 222 for specific control. Becomes As a result, even if the configuration is such that the "0" clearing to a predetermined storage area in the stack area 222 for specific control is restricted by the load instruction, the flag register of the main CPU 63 is cleared to "0". Is possible.

The flag register may be initialized instead of clearing the flag register to "0". That is, when the supply of the operating power to the main CPU 63 is started, the flag register of the main CPU 63 is temporarily cleared to "0" and then the information is set to the initial state. In S6307 and S6312, the flag register may be set so as to be in this initial state. In this case, the flag register is set so as to be in the initial state also in steps S6314 to S6322, so that the state of the flag register is set to the non-specific control when returning to the process corresponding to the specific control. It is possible to return to the state immediately before the processing corresponding to is started.

Further, in steps S6302 to S6307 and step S6312, instead of the configuration in which the flag register of the main CPU 63 is cleared to “0”, the configuration may be such that all flag registers are set to “1”. In this case, also in steps S6314 to S6322, by setting "1" in all of the flag registers, when returning to the process corresponding to the specific control, the state of the flag register starts the process corresponding to the non-specific control. It is possible to return to the state immediately before the operation.

Further, the processing of steps S6302 and S6303 may not be executed. In this case, the processing configuration can be simplified.

Further, the processing of steps S6315 and S6316 may not be executed. In this case, the processing configuration can be simplified.

Further, instead of the configuration of executing the processes of steps S6302 to S6306, as “LD HL,0”, the load command clears the HL register to “0” and then the HL register cleared to “0” is pushed. Thus, the flag register of the main CPU 63 may be cleared to “0” by saving the information in the stack area 222 for specific control and then returning the saved information to the AF register by the pop instruction.

Further, instead of the configuration in which the process of clearing the flag register to “0” is executed in the process corresponding to the specific control, the process may be executed in the process corresponding to the non-specific control.

<Twenty-eighth embodiment>
In this embodiment, the processing configuration of the management processing is different from that of the fifteenth embodiment. Hereinafter, a configuration different from that of the fifteenth embodiment will be described. The description of the same configuration as the fifteenth embodiment is basically omitted.

FIG. 98 is a flowchart showing the management processing executed by the main CPU 63 in this embodiment. The processes of steps S6401 to S6416 in the management process are executed by the main CPU 63 using the specific control program and the specific control data.

First, in order to prohibit the occurrence of the timer interrupt processing (FIG. 69), interrupt prohibition is set (step S6401). This prevents the timer interrupt process (FIG. 69), which is a process corresponding to the specific control, from being interrupted and activated in the middle of a management execution process, which will be described later, which is a process corresponding to the non-specific control. Is possible.

After that, as "PUSH WA", a push instruction causes the information in the WA register (that is, the W register and the A register) of the main CPU 63 to correspond to the current stack pointer information of the main CPU 63 in the stack area 222 for specific control. The storage area and the storage area in the next writing order with respect to the storage area are saved (step S6402). Since the W register and the A register of the main CPU 63 each have an information amount of 8 bits (1 byte), the information of the W register and the A register are individually saved in two storage areas having consecutive addresses. It When the push command is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area two in the writing order in the stack area 222 for specific control.

After that, the information of the flag register of the main CPU 63 is overwritten in the A register of the main CPU 63 by a load instruction as "LD A, PSW" (step S6403). In this case, the flag register and the A register both have an information amount of 8 bits (1 byte). Then, as "LD (_FGBUF), A", the load instruction saves the information in the A register of the main CPU 63 to the FG buffer set in the work area 221 for specific control (step S6404). Since the information in the flag register is overwritten in the A register in step S6403, the information in the flag register is saved in the work area 221 for specific control by executing step S6404.

After that, as the "POP WA", the information of the WA register saved in the stack area 222 for specific control in step S6402 is restored to the WA register of the main CPU 63 by the pop command (step S6405). As a result, even if the A register is used to save the information in the flag register to the work area 221 for specific control, the state of the A register can be returned to the state before the saving. Become. When the pop instruction is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area in which the write order in the stack area 222 for specific control is two before.

After that, the management execution process is started by reading the program of the subroutine corresponding to the management execution process set in the non-specific control program (step S6406). In this case, the information for specifying the return address of the management process after the execution of the management execution process is written in the stack area 222 for specific control by the push command. Then, when the management execution processing is completed, the information for specifying the return address is read by the pop command, and the program for the management processing indicated by the return address is returned to.

The content of the management execution process is the same as the management execution process (FIG. 71) in the fifteenth embodiment. Therefore, before the check process is started in the management execution process, each information of the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63 is saved in the work area 223 for non-specific control. In addition, the information saved in the work area 223 for non-specific control after the check processing in the management execution processing is stored in the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63. Will be returned to. This allows the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63 to be in the same state before and after the check process.

However, the present invention is not limited to this, and the processing content of the management execution processing may be the same as the management execution processing (FIG. 78) in the seventeenth embodiment, and the management execution processing in the eighteenth embodiment. The configuration may be the same as that of (FIG. 79) or the same as the management execution process (FIG. 80) of the nineteenth embodiment.

When returning to the management processing program after the execution of the management execution processing, processing for returning the information in the flag register of the main CPU 63 to the state before the execution of the management execution processing is executed. Specifically, first, as "PUSH HL", a push instruction saves the information in the HL register of the main CPU 63 to the stack area 222 for specific control (step S6407). After the execution of the push instruction, the information of the stack pointer of the main CPU 63 is the information corresponding to the storage area in the next writing order with respect to the storage area in which the information of the HL register is saved in the stack area 222 for specific control. Become.

After that, the information of the WA register of the main CPU 63 is saved in the stack area 222 for specific control by a push command as "PUSH WA" (step S6408). After the execution of the push instruction, the information of the stack pointer of the main CPU 63 is the information corresponding to the storage area in the next writing order with respect to the storage area in which the information of the WA register is saved in the stack area 222 for specific control. Become.

After that, the information of the stack pointer of the main CPU 63 is overwritten in the HL register of the main CPU 63 by the load instruction as "LD HL,SP" (step S6409). In this case, since the amount of information of the stack pointer is 16 bits and the amount of information of each of the H register and the L register is 8 bits, information of 8 bits consecutive from the upper side of the stack pointer is H register. , And 8-bit information consecutive from the lower side of the stack pointer is overwritten on the L register.

After that, the information of the flag register saved in the FG buffer in the work area 221 for specific control in step S6406 is overwritten in the A register of the main CPU 63 by a load instruction as "LD A, (_FGBUF)" (step S6410). Then, as "LD (HL), A", by the load instruction, the main side is stored in the 1-byte storage area corresponding to the information of the stack pointer stored in the HL register of the main side CPU 63 in the stack area 222 for specific control. The information in the A register of the CPU 63 is stored (step S6411). As a result, the information of the flag register saved in the FG buffer in the work area 221 for specific control in step S6404 is saved in the stack area 222 for specific control.

After that, as "LDSP, SP-1," the load instruction updates the information of the stack pointer of the main CPU 63 to the information of the address of the storage area to be written next in the stack area 222 for specific control. (Step S6412). When the stack area 222 for specific control is used, the information to be stored is stored from the storage area of the last address in the stack area 222 for specific control, and is added each time the information to be stored is added. The storage area of the storage destination is changed toward the first address side in the stack area 222. Therefore, in step S6412, the information of the stack pointer of the main CPU 63 is updated to the information of the address corresponding to the storage area on the side where the address is smaller by one in the stack area 222 for specific control. By executing the processing of step S6412, the storage areas of the next order are set as the storage objects of the information by the next push command with respect to the storage areas in which the information of the A register is saved in step S6411, and The storage area in which the information of the A register is saved in S6411 is set as the information read target of the next pop command.

After that, as a "POP PSW", a pop instruction is used to read information from the storage area in the write order immediately before the storage area corresponding to the information of the stack pointer of the main CPU 63 in the stack area 222 for specific control, The read information is overwritten in the flag register of the main CPU 63 (step S6413). The information of the stack pointer of the main CPU 63 immediately before the execution of the pop instruction in step S6413 is the information corresponding to the storage area in the next writing order with respect to the storage area in which the information of the A register is saved in step S6411. Is becoming Therefore, the storage area in the write order that is one before the storage area corresponding to the information of the stack pointer of the main CPU 63 in the stack area 222 for specific control is the storage area in which the information of the A register is saved in step S6411. It becomes an area. Then, by overwriting the flag register of the main CPU 63 with the information read from this storage area, the information of the flag register saved in the FG buffer in the work area 221 for specific control in step S6404 is the flag of the main CPU 63. It will be restored to the register. When the pop instruction is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area in which the writing order in the stack area 222 for specific control is one before.

After that, as the "POP WA", the information of the WA register saved in the stack area 222 for specific control in step S6408 is restored to the WA register of the main CPU 63 by the pop command (step S6414). When the pop instruction is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area in which the write order in the stack area 222 for specific control is two before. As "POP HL", the pop instruction is used to restore the information of the HL register saved in the stack area 222 for specific control in step S6407 to the HL register of the main CPU 63 (step S6415). When the pop instruction is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area in which the write order in the stack area 222 for specific control is two before.

After that, the interrupt permission is set to switch from the state in which the generation of the timer interrupt process (FIG. 69) is prohibited to the state in which it is permitted (step S6416). This enables a new execution of the timer interrupt process.

According to the above configuration, when the process corresponding to the non-specific control is started from the situation where the process corresponding to the specific control is being executed, the information in the flag register of the main CPU 63 is not stored in the stack area 222 for the specific control. The work area 221 for specific control can be saved. Then, when the process corresponding to the non-specific control is returned to the process corresponding to the specific control, the information of the flag register saved in the work area 221 for the specific control is the flag of the main CPU 63. It is restored to the register. As a result, the information may be returned to the flag register of the main CPU 63 from the storage area of the specific control work area 221 designated on the program without referring to the information of the stack pointer of the main CPU 63. Even when the information of the stack pointer of the side CPU 63 is rewritten due to noise or the like, the information can be restored to the flag register of the main side CPU 63.

Further, instead of the configuration in which the process of saving the information in the flag register in the main RAM 65 is performed in the process corresponding to the specific control, the configuration may be performed in the process corresponding to the non-specific control. Further, instead of the configuration in which the process of returning the flag register information saved in the main RAM 65 to the flag register of the main CPU 63 is executed in the process corresponding to the specific control, the process corresponding to the non-specific control is performed. It may be configured to be executed.

<Twenty-ninth Embodiment>
In this embodiment, the processing configuration of the management processing is different from that of the fifteenth embodiment. Hereinafter, a configuration different from that of the fifteenth embodiment will be described. The description of the same configuration as the fifteenth embodiment is basically omitted.

FIG. 99 is a flowchart showing the management processing executed in the main CPU 63 in this embodiment. The processes of steps S6501 to S6519 in the management process are executed by the main CPU 63 using the specific control program and the specific control data.

First, in order to prohibit the occurrence of the timer interrupt processing (FIG. 69), interrupt prohibition is set (step S6501). This prevents the timer interrupt process (FIG. 69), which is a process corresponding to the specific control, from being interrupted and activated in the middle of a management execution process, which will be described later, which is a process corresponding to the non-specific control. Is possible.

Then, as "PUSH HL", the push instruction causes the information of the HL register (that is, the H register and the L register) of the main CPU 63 to correspond to the information of the current stack pointer of the main CPU 63 in the stack area 222 for specific control. The storage area and the storage area in the next writing order with respect to the storage area are saved (step S6502). Since the H register and the L register of the main CPU 63 each have an information amount of 8 bits (1 byte), the information of the H register and the L register are individually saved in two storage areas having consecutive addresses. R. When the push command is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area two in the writing order in the stack area 222 for specific control.

Then, as "PUSH AF", a push instruction stores each of the information of the A register of the main CPU 63 and the information of the flag register corresponding to the information of the current stack pointer of the main CPU 63 in the stack area 222 for specific control. The area and the storage area in the next writing order with respect to the storage area are saved (step S6503). Since the A register and the flag register of the main CPU 63 each have an information amount of 8 bits (1 byte), the information of the A register and the information of the flag register are individually stored in two storage areas having consecutive addresses. Evacuated. When the push command is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area two in the writing order in the stack area 222 for specific control.

After that, as "POP HL", the pop instruction overwrites the HL register of the main CPU 63 with the A register information and the flag register information saved in the stack area 222 for specific control in step S6503 (step S6504). .. In this case, the information of the A register saved in the stack area 222 for specific control is overwritten in the H register of the main CPU 63, and the information of the flag register saved in the stack area 222 for specific control is L of the main CPU 63. Register is overwritten. When the pop instruction is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area in which the write order in the stack area 222 for specific control is two before.

After that, as "LD A, L", the information in the L register of the main CPU 63 is overwritten in the A register of the main CPU 63 by a load instruction (step S6505). Since the information in the flag register of the main CPU 63 is overwritten in the L register in step S6504, the information in the flag register is overwritten in the A register by overwriting the information in the L register in the A register. Become. Then, as "LD (_FGBUF), A", the load instruction saves the information in the A register of the main CPU 63 to the FG buffer set in the work area 221 for specific control (step S6506). Since the information in the flag register is overwritten in the A register in step S6505, the information in the flag register is saved in the work area 221 for specific control by executing step S6506.

Then, as "PUSH HL", the push instruction causes the information of the HL register (that is, the H register and the L register) of the main CPU 63 to correspond to the information of the current stack pointer of the main CPU 63 in the stack area 222 for specific control. The storage area and the storage area in the next writing order with respect to the storage area are saved (step S6507). In this case, since the information of the A register and the information of the flag register are overwritten in the HL register in step S6504, the information of the A register and the information of the flag register are saved in the stack area 222 for specific control in step S6507. I made it. When the push command is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area two in the writing order in the stack area 222 for specific control.

After that, as "POP AF", a pop instruction overwrites the A register and the flag register of the main CPU 63 with the information of the H register and the information of the L register saved in the stack area 222 for specific control in step S6507 ( Step S6508). In this case, the information of the H register saved in the stack area 222 for specific control is overwritten in the A register of the main CPU 63, and the information of the L register saved in the stack area 222 for specific control is flagged by the main CPU 63. Register is overwritten. The information of the H register saved in the stack area 222 for specific control is the information of the A register at the time of step S6503, and the information of the L register saved in the stack area 222 for specific control is the flag at the time of step S6503. It is the information of the register. Therefore, by executing the process of step S6508, the states of the A register and the flag register of the main CPU 63 are returned to the states at the time of step S6503. When the pop instruction is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area in which the write order in the stack area 222 for specific control is two before.

After that, as "POP HL", the pop instruction is used to restore the information in the HL register saved in the stack area 222 for specific control in step S6502 to the HL register of the main CPU 63 (step S6509). As a result, the state of the HL register of the main CPU 63 returns to the state at the time of step S6502. When the pop instruction is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area in which the write order in the stack area 222 for specific control is two before.

After that, the management execution process is started by reading the program of the subroutine corresponding to the management execution process set in the non-specific control program (step S6510). In this case, the information for specifying the return address of the management process after the execution of the management execution process is written in the stack area 222 for specific control by the push command. Then, when the management execution processing is completed, the information for specifying the return address is read by the pop command, and the program for the management processing indicated by the return address is returned to.

In the management execution process, the information of the BC register, the DE register, the HL register, the IX register, and the IY register of the main CPU 63 is saved in the work area 223 for non-specific control before the check process is started. After the check processing is completed in the management execution processing, each information saved in the work area 223 for non-specific control is restored to the BC register, DE register, HL register, IX register, and IY register of the main CPU 63. As a result, the BC register, the DE register, the HL register, the IX register, and the IY register of the main CPU 63 can be set to the same state before and after the check process.

However, the present invention is not limited to this, and the processing content of the management execution processing may be the same as the management execution processing (FIG. 78) in the seventeenth embodiment, and the management execution processing in the eighteenth embodiment. The configuration may be the same as that of (FIG. 79) or the same as the management execution process (FIG. 80) of the nineteenth embodiment.

When returning to the management processing program after the execution of the management execution processing, processing for returning the information in the flag register of the main CPU 63 to the state before the execution of the management execution processing is executed. Specifically, first, as "PUSH HL", a push instruction saves the information in the HL register of the main CPU 63 to the stack area 222 for specific control (step S6511). After the execution of the push instruction, the information of the stack pointer of the main CPU 63 is the information corresponding to the storage area in the next writing order with respect to the storage area in which the information of the HL register is saved in the stack area 222 for specific control. Become.

Then, as "PUSH AF", a push instruction stores each of the information of the A register of the main CPU 63 and the information of the flag register corresponding to the current stack pointer information of the main CPU 63 in the stack area 222 for specific control. The area and the storage area of the next writing order are saved to the storage area (step S6512). Since the A register and the flag register of the main CPU 63 each have an information amount of 8 bits (1 byte), the information of the A register and the information of the flag register are individually stored in two storage areas having consecutive addresses. Evacuated. When the push command is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area two in the writing order in the stack area 222 for specific control.

After that, as “POP HL”, the pop instruction overwrites the HL register of the main CPU 63 with the information of the A register and the information of the flag register saved in the stack area 222 for specific control in step S6512 (step S6513). .. In this case, the information of the A register saved in the stack area 222 for specific control is overwritten in the H register of the main CPU 63, and the information of the flag register saved in the stack area 222 for specific control is L of the main CPU 63. Register is overwritten. When the pop instruction is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area in which the write order in the stack area 222 for specific control is two before.

After that, the information of the flag register at the time of step S6503 saved in the FG buffer in the work area 221 for specific control in step S6506 by the load instruction as “LD A, (_FGBUF)” is the A register of the main CPU 63. (Step S6514). Then, as "LDL, A", the information in the A register of the main CPU 63 is overwritten in the L register of the main CPU 63 by the load instruction (step S6515). Since the information of the flag register of the main CPU 63 at the time of step S6503 is restored to the A register in step S6514, the L register is overwritten with the information of the A register, so that the L register at the time of step S6503. The information in the flag register is overwritten.

Then, as "PUSH HL", the push instruction causes the information of the HL register (that is, the H register and the L register) of the main CPU 63 to correspond to the information of the current stack pointer of the main CPU 63 in the stack area 222 for specific control. The storage area and the storage area in the next writing order with respect to the storage area are saved (step S6516). In this case, since the information of the A register at the time of step S6512 is overwritten in the H register in step S6513, the information of the A register is saved in the stack area 222 for specific control in step S6516. Become. Since the information of the flag register at the time of step S6503 is overwritten in the L register in step S6515, the information of the flag register is saved in the stack area 222 for specific control in step S6516.

After that, as "POP AF", by the pop instruction, the information of the H register and the information of the L register saved in the stack area 222 for specific control in step S6516 are overwritten in the A register and the flag register of the main CPU 63 ( Step S6517). In this case, the information of the H register saved in the stack area 222 for specific control is overwritten in the A register of the main CPU 63, and the information of the L register saved in the stack area 222 for specific control is flagged by the main CPU 63. Register is overwritten. The information of the H register saved in the stack area 222 for specific control is the information of the A register at the time of step S6512, and the information of the L register saved in the stack area 222 for specific control is the flag at the time of step S6503. It is the information of the register. Therefore, by executing the process of step S6517, the state of the A register of the main CPU 63 returns to the state of step S6512, and the state of the flag register returns to the state at the time of step S6503.

Incidentally, the A register of the main CPU 63 is not used in the management execution process. Therefore, the state of the A register at the time of step S6512 is the state of the A register at the time of step S6508, and the state of the A register at the time of step S6508 is the state of the A register at the time of step S6503. Therefore, by executing the process of step S6517, the states of the A register and the flag register of the main CPU 63 are returned to the states at the time of step S6503. When the pop instruction is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area in which the write order in the stack area 222 for specific control is two before.

After that, as "POP HL", the information of the HL register saved in the stack area 222 for specific control in step S6511 is returned to the HL register of the main CPU 63 by the pop command (step S6518). As a result, the state of the HL register of the main CPU 63 returns to the state at the time of step S6511. When the pop instruction is executed, the information of the stack pointer of the main CPU 63 is updated to the information corresponding to the storage area in which the write order in the stack area 222 for specific control is two before.

Thereafter, interrupt permission is set to switch from the state in which the generation of the timer interrupt process (FIG. 69) is prohibited to the state in which it is permitted (step S6519). This enables a new execution of the timer interrupt process.

According to the above configuration, the information of the flag register of the main CPU 63 is directly executed by the load instruction without executing the process of directly overwriting the information of the flag register from the flag register of the main CPU 63 to another register of the main CPU 63. Can be saved in the work area 221 for specific control.

Note that the information in the flag register is overwritten by the load instruction as "LD (_FGBUF), L" after executing the process in step S6504 instead of executing the process in steps S6505 to S6508. The configuration may be such that the information in the flag register is saved in the work area 221 for specific control by saving the information in the L register in the FG buffer.

Also, without performing the processing of steps S6514 and S6515, instead of performing the processing of step S6513, as a "LDL, (_FGBUF)", by the load instruction, the work area for specific control. A configuration may be adopted in which the information in the flag register saved in 221 is overwritten in the L register.

Further, instead of the configuration in which the process of saving the information in the flag register in the main RAM 65 is performed in the process corresponding to the specific control, the configuration may be performed in the process corresponding to the non-specific control. Further, instead of the configuration in which the process of returning the flag register information saved in the main RAM 65 to the flag register of the main CPU 63 is executed in the process corresponding to the specific control, the process corresponding to the non-specific control is performed. It may be configured to be executed.

<Thirtieth Embodiment>
In this embodiment, the processing configuration executed by the main CPU 63 is different from that of the fifteenth embodiment. Hereinafter, a configuration different from that of the fifteenth embodiment will be described. The description of the same configuration as the fifteenth embodiment is basically omitted.

FIG. 100 is a flowchart showing the main processing executed in the main CPU 63 in this embodiment. The processes of steps S6601 to S6621 in the main process are executed by using the specific control program and the specific control data in the main CPU 63.

First, power-on wait processing is executed (step S6601). In the power-on wait process, for example, the main process is started and waits for a predetermined time for waiting (specifically, 1 second) without proceeding to the next process. During the execution period of the power-on weight process, the operation start and initial setting of the symbol display device 41 are completed. After that, access to the main RAM 65 is permitted (step S6602).

After that, it is determined whether or not "1" is set in the power failure flag provided in the work area 221 for specific control in the main RAM 65 (step S6603). When the power failure flag is set to "1" (step S6603: YES), checksums are calculated for the specific control work area 221 and the specific control stack area 222 (step S6604).

The calculation method of the checksum is arbitrary, but for example, a calculation method of adding all the numerical values of the storage area subject to the checksum calculation can be used. The method of calculating the checksum is the same as the method of calculating the checksum in the power failure process described later. The checksum calculated in the power failure process to be described later is stored in the specific control work area 221, and the storage area of the specific control work area 221 in which this checksum is stored is the checksum calculation. At that time, it is excluded from the storage areas to be calculated.

That is, when the checksum is calculated, some of the storage areas in the work area 221 for specific control and the stack area 222 for specific control are to be calculated. In the storage area to be calculated, the checksum is calculated in the power failure process when the supply of the operating power to the MPU 62 is stopped, and then the supply of the operating power to the MPU 62 is restarted to execute the process of step S6604. Until that time, when the power supply such as the backup power to the work area 221 for specific control and the stack area 222 for specific control is continued, the information area is basically not rewritten. Therefore, the information of the work area 221 for specific control and the stack area 222 for specific control is not changed from the supply of the operation power to the MPU 62 to the restart of the supply of the operation power to the MPU 62. In this case, the checksums of the specific control work area 221 and the specific control stack area 222 are the same as immediately before the supply of the operating power to the MPU 62 is stopped. In addition, in the storage area to be calculated when calculating the checksum, an area (specifically, a set value counter) in which the set value information indicating the set state of the pachinko machine 10 in the work area 221 for specific control is set )It is included.

After that, the work area 221 for the specific control and the stack area for the specific control, which are calculated in the power failure process executed immediately before the supply of the operating power to the MPU 62 is stopped and are stored in the work area 221 for the specific control. The checksum for 222 is read from the work area 221 for specific control, and the read checksum is compared with the checksum calculated in step S6604 (step S6605). Then, it is determined whether the checksums match each other (step S6606).

Here, the power failure information storage processing executed by the main CPU 63 will be described with reference to the flowchart of FIG. The power failure information storage process is executed in step S6801 in the timer interrupt process (FIG. 103) described later.

In the power failure information storage processing, first, the repeat counter provided in the specific control work area 221 is set with the information "10" that is the number of times of power failure signal repetition (step S6701), and the specific control work area is also set. The power failure detection counter provided in 221 is cleared to "0" (step S6702).

After that, a process of reading the information of the power failure signal received in the input port of the MPU 62 is executed (step S6703). In this case, when the power failure signal (LOW level power failure signal) corresponding to the fact that the power is not cut off is received, the information “0” is stored in the input port as the non-power failure information, When a power failure signal (HI level power failure signal) corresponding to the occurrence of power cutoff is received, information "1" is stored in the input port as power failure occurrence information. In step S6703, a process of reading the information of the power failure signal into the register of the main CPU 63 is executed.

When the information of the power failure signal read in step S6703 corresponds to the occurrence of power failure (occurrence of power failure) (step S6704: YES), the numerical information of the power failure detection counter is incremented by 1 (step S6705). When a negative determination is made in step S6704 or when the processing of step S6705 is executed, the numerical value information of the repetition counter is decremented by 1 (step S6706). Then, it is determined whether or not the numerical information of the repeat counter after the subtraction of 1 is "0" (step S6707). When a negative determination is made in step S6707, the process returns to step S6703 and the processes of steps S6703 to S6706 are repeated. On the other hand, if an affirmative decision is made in step S6707, the operation proceeds to step S6708.

In step S6708, it is determined whether or not the current numerical information of the power failure detection counter is equal to or greater than the trigger reference number of times corresponding to the occurrence of the power failure. If it is less than the trigger reference number of times, this power failure information storage processing is ended as it is. On the other hand, if the number of times is equal to or greater than the trigger reference number, the power outage process of steps S6709 to S6712 is executed.

Specifically, first, "1" is set to the power failure flag provided in the work area 221 for specific control (step S6709). As a result, when the power failure process is executed normally and the information storage and holding in the main RAM 65 is normally performed, the power supply for operation to the main CPU 63 is restarted, the specific control is performed. The power failure flag of the work area 221 of 1 is set to "1".

After that, checksums are calculated for the specific control work area 221 and the specific control stack area 222 (step S6710). In this case, the storage areas in the specific control work area 221 and the specific control stack area 222 that are the calculation targets when the checksum is calculated are the checksum calculation targets in step S6604 of the main process (FIG. 100). The storage area is the same as the work area 221 for specific control and the stack area 222 for specific control. In addition, the storage area to be calculated when calculating the checksum is an area (specifically, a set value counter) in which information of set values indicating the set state of the pachinko machine 10 in the work area 221 for specific control is set. )It is included. Then, the calculated checksum is stored in a storage area for storing the checksum in the work area 221 for specific control, which is excluded from the checksum calculation target.

After that, all the output port information in the register of the main CPU 63 is set to "0" (step S6711), and access to the main RAM 65 is prohibited (step S6712). Then, the infinite loop is continued until the power is completely cut off and the processing cannot be executed.

Since the power failure information storage process is executed as the first process of the timer interrupt process, it is not necessary to execute the timer interrupt process in the middle of power recovery. As a result, it is not necessary to store the address of the process being executed at the time of the power failure in the main RAM 65 as stack information, and the processing load of the process at the time of the power failure can be reduced.

Returning to the description of the main processing (FIG. 100), if a negative determination is made in step S6603 or step S6606, clear processing at the time of non-setting update is executed (step S6607). In the clear process at the time of non-setting update, in the specific control work area 221, the specific control is performed except for the area (specifically, the setting value counter) in which the setting value information indicating the setting state of the pachinko machine 10 is set. The work area 221 for use is cleared to "0" and the initial setting is executed. As a result, the area indicating whether or not the winning/winning lottery mode is the high-probability mode is cleared to "0". The mode is a low probability mode. In addition, the game times are not being executed, the opening/closing execution mode is not being executed, and the general-purpose display unit 38a is not being variably displayed, and the general electric accessory 34a is in the closed state. It becomes a situation. Further, since the hold storage area 65a and the universal electric power reserve area 65c provided in the work area 221 for specific control are also cleared to "0", the reserved information for the special figure display section 37a is deleted and the general figure display section is deleted. The hold information for 38a is deleted. Further, in the clear processing at the time of non-setting update, the stack area 222 for specific control is cleared to “0” and the initial setting is executed. Further, in the clearing process at the time of non-setting update, various registers of the main CPU 63 are also cleared to “0” and then the initial setting is executed.

On the other hand, in the clear processing at the time of non-specific update, the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to "0". As a result, even if the power failure flag is not set to "1" because the power failure process was not executed normally, the work area 223 for non-specific control and the stack area 224 for non-specific control are "0". It becomes possible not to be cleared. Even if an error occurs in the checksum of the work area 221 for specific control and the stack area 222 for specific control, the work area 223 for non-specific control and the stack area 224 for non-specific control are cleared to “0”. It is possible to prevent it.

When a negative determination is made in step S6603 or step S6606, after executing the clear processing at the time of non-setting update in step S6607, by checking the value of the set value counter in the work area 221 for specific control, the pachinko machine is confirmed. It is determined whether the set value of 10 is normal (step S6608). Specifically, when the set value set in the set value counter is any of "setting 1" to "setting 6", it is determined to be normal, and when it is "0" or 7 or more, there is an abnormality. Judge that there is. If the set value is abnormal (step S6608: NO), the process for setting a new set value (step S6619 to step S6621) described below is executed. As a result, it is possible to monitor whether or not the set value is normal even when the negative determination is made in step S6603 or step S6606 and the clear processing at the time of non-setting update (step S6607) is executed. In addition, when the set value is abnormal, the set value can be reset.

When the set value is normal (step S6608: YES), power-on setting processing is executed (step S6609). In the power-on setting process, a predetermined area of the work area 221 for specific control such as initialization of the power failure flag is set to an initial value, and a command corresponding to the current game state is transmitted to the voice emission control device 81.

Although the main CPU 63 is configured to periodically execute the timer interrupt process, the generation of the timer interrupt process is prohibited when the main process is started. The state in which the generation of the timer interrupt process is prohibited is released at the timing before the process of step S6609 is completed and the process of step S6610 is executed, and the execution of the timer interrupt process is permitted. As a result, when the supply of the operating power to the main CPU 63 is started, the power-on setting process of step S6609 ends, and the timer interrupt process is not executed until the stage before the process of step S6610 is started. Therefore, the processing for advancing the game in the main CPU 63 is not started until this situation is reached.

After that, the process proceeds to the residual process of steps S6610 to S6613. That is, the main CPU 63 is configured to periodically execute the timer interrupt process, but a residual time is generated between one timer interrupt process and the next timer interrupt process. This remaining time will vary depending on the processing completion time of each timer interrupt processing, but the remaining processing of steps S 6610 to S 6613 is repeatedly executed by utilizing this irregular time. In this respect, it can be said that the residual process of steps S6610 to S6613 is an irregular process executed irregularly. In steps S6610 to S6613, the same processes as steps S113 to S116 of the main process (FIG. 9) in the first embodiment are executed.

As described above, in the present embodiment, when the supply of operating power to the main CPU 63 is started, "1" is not set in the power failure flag of the work area 221 for specific control, or the checksums do not match. In this case, if the set value is normal after executing the clear process at the time of non-setting update (step S6608: YES), the process proceeds to the process of advancing the game. As a result, even if the power failure flag is not set to "1" because the power failure process was not executed normally, the power is turned on again after the operating power supply to the main CPU 63 is started. There is no need to turn it off. Even if an abnormality occurs in the checksum of the specific control work area 221 and the specific control stack area 222, the power is turned on and off again after the supply of the operating power to the main CPU 63 is started. You don't have to do anything.

When a positive determination is made in both step S6603 and step S6606, it is determined whether or not the set value of the pachinko machine 10 is normal by checking the value of the set value counter in the work area 221 for specific control (step S6614). ). Specifically, when the set value set in the set value counter is any of "setting 1" to "setting 6", it is determined to be normal, and when it is "0" or 7 or more, there is an abnormality. Judge that there is. If the set value is abnormal (step S6614: NO), the process for setting a new set value (step S6619 to step S6621) described below is executed.

If the set value is normal (step S6614: YES), it is determined whether or not the reset button 68c has been pressed (step S6615), and whether the setting key insertion portion 68a has been turned ON using the setting key. It is determined whether or not (step S6616), the front door frame 14 is open with respect to the inner frame 13 (step S6617), and the gaming machine main body 12 is open with respect to the outer frame 11. It is determined whether there is any (step S6618).

In the present embodiment, a front door opening sensor 95 for detecting whether or not the front door frame 14 is opened with respect to the inner frame 13 is electrically connected to the main CPU 63, and the front door opening sensor The detection result of 95 is input to the main CPU 63. In this case, when the front door frame 14 is closed with respect to the inner frame 13, the front door open sensor 95 transmits a close detection signal to the main CPU 63, and the front door frame 14 is opened with respect to the inner frame 13. In the case of, the front door opening sensor 95 sends an opening detection signal to the main CPU 63. The main CPU 63 specifies that the front door frame 14 is in the closed state when receiving the closing detection signal from the front door opening sensor 95, and when receiving the opening detection signal from the front door opening sensor 95. The front door frame 14 is specified to be in the open state.

Further, in the present embodiment, a main body opening sensor 96 for detecting whether or not the gaming machine main body 12 is in an open state with respect to the outer frame 11 is electrically connected to the main CPU 63, and the main body opening sensor The detection result of 96 is input to the main CPU 63. In this case, when the gaming machine main body 12 is closed with respect to the outer frame 11, the main body opening sensor 96 transmits a closing detection signal to the main CPU 63, and the gaming machine main body 12 is opened with respect to the outer frame 11. In some cases, the main body open sensor 96 sends an open detection signal to the main CPU 63. The main CPU 63 specifies that the gaming machine main body 12 is in the closed state when receiving the closing detection signal from the main body opening sensor 96, and determines when the opening detection signal is received from the main body opening sensor 96. It specifies that the main body 12 is in the open state.

If the reset button 68c has not been pressed (step S6615: NO), the power-on setting process is executed in step S6609, and then the remaining process of steps S6610 to S6613 is repeated. In other words, when the reset button 68c is not pressed, the process for clearing the work area 221 for specific control and the stack area 222 for specific control is not performed, and the process proceeds to control the progress of the game. ..

When the reset button 68c is being pressed (step S6615: YES), and when a negative determination is made in any of steps S6616 to S6618, after executing the clear processing at the time of non-setting update (step S6607). ), on condition that the set value is normal (step S6608: YES), the process proceeds to the process for controlling the progress of the game in step S6609 and subsequent steps. The processing content of the clear processing at the time of non-setting update is as already described.

When the reset button 68c is being pressed (step S6615: YES), and when a positive determination is made in all of steps S6616 to S6618, processing for updating the set value is executed. Also, when it is determined in step S6608 or step S6614 that the set value is abnormal, the process for updating the set value is executed.

Specifically, first, a setting value copy process is executed (step S6619). In the copy processing, information on a setting value counter used to specify the setting value of the pachinko machine 10 in the specific control work area 221 is stored in a copy area provided in the specific control work area 221. .. As a result, even if the setting value counter information is cleared to "0" in the subsequent clearing process at the time of updating the setting (step S6620), the book before the clearing process at the time of updating the setting value is executed. It is possible to grasp the set value of the pachinko machine 10 (that is, the set value of the pachinko machine 10 before the supply of the operating power to the pachinko machine 10 is stopped).

After that, a clear process at the time of updating the setting is executed (step S6620). In the clear process at the time of updating the settings, the work area 221 for the specific control is set to “0 "Clear and execute the initial settings. As a result, the game times are not being executed, the opening/closing execution mode is not being executed, and the general-purpose display unit 38a is not being variably displayed, and the general electric accessory 34a is in the closed state. There is a certain situation. Further, since the hold storage area 65a and the universal electric power reserve area 65c provided in the work area 221 for specific control are also cleared to "0", the reserved information for the special figure display section 37a is deleted and the general figure display section is deleted. The hold information for 38a is deleted. Further, in the clearing process at the time of updating the setting, the stack area 222 for specific control is cleared to “0” and the initial setting is executed. Further, in the clearing process at the time of updating the setting, the setting value counter used for specifying the setting value of the pachinko machine 10 is cleared to “0”. Further, in the clearing process at the time of updating the settings, various registers of the main CPU 63 are also cleared to “0” and then the initial setting is executed.

On the other hand, in the clearing process at the time of updating the settings, the area indicating whether the win/win lottery mode is the high-probability mode is not cleared to "0". Can be maintained in the mode before the supply of the operating power to the pachinko machine 10 is stopped. In addition, since the copy area is not cleared to "0" in the clearing process at the time of setting update, it is possible to specify the set value set before the clearing process at the time of setting update is executed. The configuration is not limited to the above configuration, and the setting value counter used for specifying the setting value of the pachinko machine 10 may not be cleared to “0” in the clearing process at the time of updating the setting. In the clearing process, the area indicating whether the winning/winning lottery mode is the high-probability mode may be cleared to "0".

In the clear processing at the time of updating the settings, the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to "0". As a result, even if the setting value updating process capable of changing the setting value of the pachinko machine 10 is executed, the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to "0". It becomes possible to do so.

After that, in step S6621, the setting value update processing is executed. The processing content of the setting value updating processing is the same as the setting value updating processing (FIG. 85) in the twenty-second embodiment. After executing the setting value update process, the process proceeds to the process for controlling the progress of the game after step S6609.

According to the above configuration, when the setting value is abnormal, the setting value updating process is started without requiring a special operation by the game hall manager. Then, when the set value updating process is completed, the process proceeds to a process for controlling the progress of the game. As a result, it becomes possible to play the game in the situation where the normal set value is set. On the other hand, in order to complete the set value update processing, since an OFF operation by the set key to the set key insertion portion 68a is required, the set value is arbitrarily set by a person other than the manager of the game hall and the game is started. It is possible to prevent the occurrence of the event of being lost.

Next, a configuration for forcibly stopping the progress of the game when the main CPU 63 cannot perform various processes normally will be described. FIG. 102A is a block diagram for explaining the configuration of the MPU 62.

As shown in FIG. 102A, the MPU 62 is provided with a main CPU 63, a main ROM 64, and a main RAM 65, as well as a reset signal output unit 251 and a program monitoring unit 252. The reset signal output unit 251 has a function of outputting a reset signal to the main CPU 63. Specifically, the reset signal output unit 251 uses the reset signal as the HI level signal when the operating power is supplied from the power supply/launch control device 78 and the output disable condition is not satisfied. The CPU 63 outputs the reset signal to the main CPU 63 when the power supply/launch control device 78 does not supply the operating power, or when the operating disable is satisfied even when the operating power is supplied. Do not output to. The main CPU 63 executes various processes when the operating power is supplied from the power supply/launch control device 78 and the reset signal is received from the reset signal output unit 251, and Even when the operating power is supplied, if the reset signal is not received from the reset signal output unit 251, various processes are not executed. In addition, when the main CPU 63 is supplied with operating power from the power supply/launch control device 78, it is switched from the state in which the reset signal is not received from the reset signal output unit 251 to the state in which the reset signal is received. Then, the main process (FIG. 100) is started.

The program monitoring unit 252 has a function of monitoring whether or not the main CPU 63 can normally perform various processes. Specifically, the program monitoring unit 252 monitors whether the value of the program counter provided in the main CPU 63 is an abnormal value. The program counter is for storing an address where an instruction to be executed in the main CPU 63 is stored. A possible value is set for the program counter, and the program monitoring unit 252 monitors whether the value of the program counter is a value other than the possible values. Further, the program monitoring unit 252 monitors whether or not the address designated as the write destination area is an abnormal address when the information is written to the specific control work area 221 by the load instruction. Note that the program monitoring unit 252 may be configured to monitor whether or not the address designated as the read target area is an abnormal address when the information is read from the specific control work area 221 by the load instruction.

When the program monitoring unit 252 determines that the value of the program counter is an abnormal value, or when the address specified when writing information by the load instruction is determined to be an abnormal address, the reset signal output unit 251. Outputs a monitoring abnormality signal to. When the reset signal output unit 251 receives the monitoring abnormality signal from the program monitoring unit 252, the reset signal output unit 251 temporarily stops the output of the reset signal even if the operating power is supplied from the power supply/launch control device 78, and continues the stop. After the output of the reset signal is stopped for a period, the output of the reset signal is restarted. The stop continuation period is a period sufficient for the main CPU 63 to specify that the output of the reset signal is stopped. As a result, when the value of the program counter becomes an abnormal value, or when the address specified when writing the information by the load instruction becomes an abnormal address, the main CPU 63 is turned OFF/ON through the reset signal. The main processing is executed at.

FIG. 102B is a time chart showing how the reset signal output section 251 outputs the reset signal. 102(b1) shows a period during which operating power is supplied from the power supply/launch control device 78, FIG. 102(b2) shows a period during which a reset signal is output from the reset signal output unit 251, and FIG. b3) shows the timing at which the monitoring abnormality signal is output from the program monitoring unit 252.

First, the case where the monitoring abnormality signal is not output from the program monitoring unit 252 will be described. When the power supply/launch control device 78 starts supplying the operating power to the MPU 62 at the timing t1, as shown in FIG. 102(b1). , T2, the reset signal output unit 251 starts to output the reset signal as shown in FIG. After that, at the timing of t3, as shown in FIG. 102(b1), the supply of operating power from the power supply/launch control device 78 to the MPU 62 is stopped, so that the timing of t4 is reset as shown in FIG. 102(b2). The output of the reset signal from the signal output unit 251 is stopped.

Next, description will be made regarding the case where the monitoring abnormality signal is output from the program monitoring unit 252. At t5, as shown in FIG. 102(b1), supply of operating power from the power supply/launch control device 78 to the MPU 62 is started. As a result, at the timing of t6, the reset signal output unit 251 starts outputting the reset signal as shown in FIG. After that, at the timing of t7, the value of the program counter becomes an abnormal value, or the address specified when the information is written by the load instruction becomes an abnormal address, so that the program monitoring is performed as shown in FIG. 102(b3). A monitoring abnormality signal is output from the unit 252 to the reset signal output unit 251. As a result, as shown in FIG. 102(b2), the output of the reset signal from the reset signal output unit 251 is temporarily stopped at the timing of t7 and restarted at the subsequent timing of t8.

In this case, the main CPU 63 stops the execution of various processes at the timing of t7, and starts the main process (FIG. 100) at the timing of t8 which is the timing at which the rising edge of the reset signal is confirmed. However, since the process at the time of power failure is not executed when the execution of various processes of the main CPU 63 is stopped, the main process is performed in the situation where the power failure flag in the work area 221 for specific control is not set to "1" (FIG. 100). And the main process (FIG. 100) is started without saving the checksums of the work area 221 for specific control and the stack area 222 for specific control. Therefore, in the main process (FIG. 100), a negative determination is made in step S6603 or step S6606, and the clear process at the time of non-setting update (step S6607) is executed. As a result, when the program monitoring unit 252 outputs the monitoring abnormality signal when the value of the program counter becomes an abnormal value or the address specified when writing information by the load instruction becomes an abnormal address, It is possible to execute a clear process at the time of non-setting update, in which a predetermined storage area of the specific control work area 221 and the specific control stack area 222 is cleared to “0”. ..

However, in the clear processing at the time of non-setting update, the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to "0". As a result, even if the program monitoring unit 252 outputs a monitoring error signal due to an abnormal value of the program counter or an address specified when writing information by a load instruction becomes an abnormal address, It is possible to prevent the work area 223 for specific control and the stack area 224 for non-specific control from being cleared to “0”.

Returning to the explanation of FIG. 102(b), after that, at the timing of t9, as shown in FIG. 102(b1), the supply of the operating power from the power supply/launch control device 78 to the MPU 62 is stopped, so that the timing of t10 is reached. As shown in FIG. 102(b2), the output of the reset signal from the reset signal output unit 251 is stopped.

Next, the timer interrupt processing in this embodiment executed by the main CPU 63 will be described with reference to the flowchart in FIG. The timer interrupt process is executed periodically (for example, every 4 milliseconds) in a situation where the processes of steps S6610 to S6613 are executed in the main process (FIG. 100). The program corresponding to the timer interrupt process is set to the program for specific control.

In steps S6801 to S6819, the same processes as steps S5201 to S5219 of the timer interrupt process (FIG. 86) in the twenty-second embodiment are executed. These processes are executed by the main CPU 63 using a specific control program and specific control data. After that, the setting monitoring process is executed (step S6820). FIG. 104 is a flowchart showing the setting monitoring process.

By checking the value of the set value counter in the work area 221 for specific control, it is determined whether or not the set value of the pachinko machine 10 is normal (step S6901). Specifically, when the set value set in the set value counter is any of "setting 1" to "setting 6", it is determined to be normal, and when it is "0" or 7 or more, there is an abnormality. Judge that there is.

If the set value is abnormal (step S6901: NO), first, a copy process of the set value is executed (step S6902). In the copy processing, information on a setting value counter used to specify the setting value of the pachinko machine 10 in the specific control work area 221 is stored in a copy area provided in the specific control work area 221. .. As a result, it becomes possible to grasp the set value of the pachinko machine 10 before the execution of the set value updating process executed thereafter.

After that, an abnormality command indicating that the abnormality of the set value has occurred is transmitted to the voice emission control device 81 (step S6903). Upon receipt of the abnormal command, the sound emission control device 81 causes the display light emitting unit 53 to emit light in a manner corresponding to the abnormal setting value, and the speaker 54 outputs a voice message "abnormal setting value has been detected." Output. In addition, the character image "Abnormality of the set value is detected." is displayed on the pattern display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are ended when the supply of operating power to the pachinko machine 10 is stopped. However, the present invention is not limited to this, and the notification may be ended when the notification end operation is performed by the game hall manager. As the notification end operation, for example, the update button 68b may be pressed or the reset button 68c may be pressed. By confirming the notification, the game hall manager can know that the set value abnormality has occurred.

After that, the setting value update processing is executed (step S6904). That is, every time the timer interrupt process (FIG. 103) is executed, it is monitored whether or not an abnormality has occurred in the set value, and when the occurrence of the set value abnormality is identified, the set value of the pachinko machine 10 is reset. To perform the setting value update processing. The processing content of the setting value updating processing is the same as the setting value updating processing (FIG. 85) in the twenty-second embodiment. Therefore, each time the update button 68b is pressed once, the set value is updated one step at a time, and the set value being selected is confirmed by detecting the game ball with the outlet detection sensor 48a. The set value that is being updated and the set value that has been confirmed are displayed on the third notification display device 69c. After that, when the setting key insertion unit 68a is switched from the ON state to the OFF state, it is determined that the ending condition of the set value updating process is satisfied. After executing the set value updating process, the process returns to the timer interrupt process (FIG. 103).

Here, in the set value updating process, it is not determined that the ending condition is satisfied only by the setting key inserting section 68a being in the OFF state, and the setting key inserting section 68a is switched from the ON state to the OFF state. If it is determined that the termination condition is satisfied. When the setting value updating process is executed in the setting monitoring process, since the setting key insertion unit 68a is in the OFF state at the start of the setting value updating process, the end condition of the setting value updating process is satisfied. It is necessary to insert a setting key into the setting key insertion portion 68a, perform an ON operation once, and then perform an OFF operation. As a result, it becomes possible to prevent the setting value updating process from ending even though the game hall manager has not performed a regular operation.

When the setting key insertion unit 68a is switched from the ON state to the OFF state and the ending condition of the set value updating process is satisfied, by executing step S5111 in the set value updating process (FIG. 85), It is compared whether or not the set value stored in the copy area of the specific control work area 221 and the set value currently set in the set value counter in the specific control work area 221 are the same. That is, it is determined whether or not the set value set before the set value update processing (step S6904) is executed and the set value set in the current set value update processing are the same. When both set values are the same (step S5112: NO), the notification process at the time of non-change (step S5113) is executed to perform the setting maintenance notification already described. On the other hand, when the two setting values are different (step S5112: YES), the notification process at the time of change (step S5114) is executed so that the setting change notification described above is performed.

In the configuration where the setting value update process is executed when a setting value error occurs, the setting value that was set before the setting value update process was executed and the setting value that was set in the setting value update process If the set value is the same, the setting maintenance notification is given. As a result, even if the setting value update process is executed due to a setting value error, the setting maintenance notification will be performed by resetting the setting value that was set in the previous situation, and the setting value update due to the setting value error Even if the processing is executed, it is possible to clearly indicate to the player that the set value has not changed. By the way, since it is common to record the set value of each pachinko machine 10 installed in the game hall, it is possible to execute the set value update process due to the set value abnormality so that the set value becomes the recorded set value. It is possible.

Returning to the explanation of the timer interrupt processing (FIG. 103), after executing the setting monitoring processing in step S6820, the management processing is executed in step S6821. When the management process is executed, the subroutine program corresponding to the management process set in the specific control program is executed. The information for specifying the return address of the timer interrupt process in is written in the stack area 222 for specific control by the push command. When the management process ends, the pop instruction reads the information for specifying the return address, and the program returns to the timer interrupt processing program indicated by the return address.

FIG. 105 is a flowchart showing the management processing executed in the main CPU 63 in this embodiment. The processes of steps S7001 to S7005 in the management process are executed by the main CPU 63 using the specific control program and the specific control data.

First, interrupt prohibition is set in order to prohibit the occurrence of timer interrupt processing (FIG. 103) (step S7001). This prevents the timer interrupt process (FIG. 103), which is a process corresponding to the specific control, from being interrupted and activated in the middle of a management execution process, which will be described later, which is a process corresponding to the non-specific control. Is possible.

After that, as "LD (_PSWBUF), PSW", the information of the flag register of the main CPU 63 is saved in the PSW buffer set in the work area 221 for specific control by a load instruction (step S7002). The flag register includes a carry flag, a zero flag, a P/V flag, a sine flag, a half carry flag, etc., and the information in the flag register changes depending on the execution result of an arithmetic instruction, a rotate instruction, an input/output instruction, and the like. By saving such flag register information before the program of the subroutine corresponding to the management execution process is started, the flag register in the state before being changed after the subroutine is called or the subroutine is started is saved. The information can be saved in the work area 221 for specific control.

After that, the management execution process is started by reading the program of the subroutine corresponding to the management execution process set in the non-specific control program (step S7003). In this case, the information for specifying the return address of the management process after the execution of the management execution process is written in the stack area 222 for specific control by the push command. Then, when the management execution processing is completed, the information for specifying the return address is read by the pop command, and the program for the management processing indicated by the return address is returned to.

After returning to the management processing program after execution of the management execution processing, "LD PSW,(_PSWBUF)" is saved to the PSW buffer in the work area 221 for specific control in step S7002 by a load instruction. The information in the flag register is returned to the flag register of the main CPU 63 (step S7004). As a result, the information in the flag register of the main CPU 63 is restored to the information at the time when step S7002 was previously executed. That is, the information in the flag register of the main CPU 63 is restored to the information for executing the specific control.

After that, the interrupt permission is set to switch from the state in which the generation of the timer interrupt process (FIG. 103) is prohibited to the state in which it is permitted (step S7005). This enables a new execution of the timer interrupt process.

FIG. 106 is a flowchart showing the management execution process executed by the main CPU 63 in this embodiment. The processes of steps S7101 to S7116 in the management execution process are executed by the main CPU 63 using the non-specific control program and the non-specific control data.

In steps S7101 to S7108 and steps S710 to S7116, the same processing as steps S4501 to S4515 of the management execution processing (FIG. 78) in the seventeenth embodiment is executed. Also, in step S7109, another monitoring process is executed. When the separate monitoring process is executed, the subroutine program corresponding to the separate monitoring process set in the non-specific control program is executed, but after executing the separate monitoring process, the subroutine program is executed. The information for specifying the return address of the management execution process in (1) is written in the stack area 224 for non-specific control by the push command. Then, when the separate monitoring process is completed, the information for specifying the return address is read by the pop command, and the process returns to the program of the management execution process indicated by the return address.

FIG. 107 is a flowchart showing another monitoring process. The processes of steps S7201 to S7206 in the separate monitoring process are executed by the main CPU 63 using the non-specific control program and the non-specific control data.

In the separate monitoring process, it is determined whether or not the value of the pointer indicating the processing position of the process executed in the non-specific control program exceeds the normal numerical range (step S7201). Further, the information stored in the normal counter area 231, the open/close execution mode counter area 232, and the high frequency support mode counter area 233 provided in the non-specific control work area 223 is obviously abnormal information. It is determined whether or not (step S7202). For example, when the value of the normal out counter 231e in the normal counter area 231 is "0" but the value of the normal general prize winning counter 231a is 1000 or more, it is determined to be abnormal. Further, it is determined whether the information stored in the calculation result storage area 234 provided in the non-specific control work area 223 is obviously abnormal information (step S7203). For example, when any of the 62nd to 64th parameters is not "0" even though the 61st parameter is "0", it is determined to be abnormal.

When an affirmative determination is made in any of steps S7201 to S7203, it is determined that an information abnormality has occurred in the work area 223 for non-specific control, and a partial clearing process of the work area 223 for non-specific control is executed. (Step S7204). In the partial clear process, the storage areas other than the management start flag in the work area 223 for non-specific control are cleared to "0". In this case, all of the normal counter area 231, the open/close execution mode counter area 232, the high frequency support mode counter area 233, and the calculation result storage area 234 are cleared to “0”. This makes it possible to eliminate the information abnormality in the work area 223 for non-specific control.

In addition, by not clearing the management start flag to "0", it becomes possible to maintain the state in which the management start flag is already set to "1", and the pachinko machine 10 has already continued in the game hall. It is possible to prevent the pachinko machine 10 from being regulated in the shipping stage regarding the collection of the history information even though the pachinko machine 10 is used. However, the present invention is not limited to this, and in step S7204, the entire work area 223 for non-specific control including the management start flag may be cleared to "0".

Also, in step S7204, the stack area 224 for non-specific control is not cleared to "0". In the stack area 224 for non-specific control, information of various registers used in the processing corresponding to the specific control in steps S7102 to S7107 in the management execution processing (FIG. 106) is saved. In this case, by not clearing the stack area 224 for non-specific control to "0", the stack area for non-specific control is information of various registers used in the process corresponding to this specific control. It is possible to prevent the information saved in 224 from being erased. Further, the non-specific control stack area 224 stores information on the return address of the management execution process (FIG. 106) after the completion of another monitoring process. By not clearing it, it becomes possible to prevent the information at this return address from being erased.

After that, initialization processing is executed (step S7205). In the initial setting process, the initial setting is performed on the storage area for which “0” is cleared in the work area 223 for non-specific control in step S7204.

After that, a clear notification process is executed (step S7206). In the clear notification process, a command indicating that the work area 223 for non-specific control has been cleared to “0” is transmitted to the sound emission control device 81. Upon receiving the command, the sound emission control device 81 causes the display light emitting unit 53 to emit light in a mode corresponding to the forcible clearing of the work area 223 for non-specific control, and the history information is forcibly cleared from the speaker unit 54. The voice is output. Further, the character image "History information has been forcibly cleared." is displayed on the pattern display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are ended when the supply of operating power to the pachinko machine 10 is stopped. However, the present invention is not limited to this, and the notification may be ended when the notification end operation is performed by the game hall manager. As the notification end operation, for example, the update button 68b may be pressed or the reset button 68c may be pressed. By confirming the notification, the game hall manager can grasp that the work area 223 for non-specific control has been forcibly cleared.

If a negative determination is made in all of steps S7201 to S7203, or if the process of step S7206 is executed, another monitoring process is terminated and the process returns to the monitoring execution process (FIG. 106).

According to this embodiment described in detail above, the following excellent effects are exhibited.

When the program monitoring unit 252 identifies that the address specified when the information is written by the load instruction is an abnormal address, the reset signal output unit 251 turns the reset signal from OFF to ON, whereby the main CPU 63 Then, the main process (FIG. 100) is executed as in the case where the supply of operating power is newly started. When the reset signal is turned from OFF to ON, the power failure flag in the specific control work area 221 is not set to "1" and the checksum at the time of power failure is stored in the specific control work area 221. Since this has not been done, the clearing process (step S6607) at the time of non-setting update is forcedly executed. In the clear process at the time of non-setting update, the storage area other than the storage area in which the set value of the pachinko machine 10 is stored in the work area 221 for specific control is cleared to “0” and the stack area 222 for specific control is set to “ 0” is cleared, and the initial setting process of these areas is executed. As a result, when there is a possibility that information abnormality has occurred in the work area 221 for specific control or the stack area 222 for specific control, the work area 221 for specific control and the stack area 222 for specific control are On the other hand, it is possible to eliminate the information abnormality by executing the “0” clearing process and the initial setting process.

When the program monitoring unit 252 identifies that the value of the program counter of the main CPU 63 is an abnormal value, the reset signal output unit 251 turns the reset signal from OFF to ON, so that the main CPU 63 outputs the operating power. The main process (FIG. 100) is executed in the same manner as when the supply is newly started. When the reset signal is turned from OFF to ON, the power failure flag in the specific control work area 221 is not set to "1" and the checksum at the time of power failure is stored in the specific control work area 221. Since this has not been done, the clearing process (step S6607) at the time of non-setting update is forcedly executed. In the clear processing at the time of non-setting update, the internal storage area of the main CPU 63 including various registers is cleared to “0” and the initial setting processing is executed. As a result, when there is a possibility that an information abnormality has occurred in the internal storage area of the main CPU 63, the internal storage area of the main CPU 63 is cleared by executing "0" clear and initialization processing. It is possible to eliminate the information abnormality.

On the other hand, in the clear processing at the time of non-specific update, the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to "0". As a result, since the program monitoring unit 252 has identified the information abnormality as described above, “0” is cleared in the internal storage area of the main CPU 63, the specific control work area 221, and the specific control stack area 222. Even when the initial setting process is executed with, it is possible to prevent the information of the game history from being erased and prevent the information of the management result of the game history from being erased. It becomes possible to do.

If the power failure flag is not set to "1" in the main process (Fig. 100) when the supply of operating power to the main CPU 63 is started, or if the checksums do not match, clear at the time of non-setting update In the configuration in which the process (step S6607) is executed, when the program monitoring unit 252 identifies the occurrence of the information abnormality, the reset signal is turned from OFF to ON so that the power failure flag is not set to "1". At the same time, the main process (FIG. 100) is executed in a situation where the checksum is not stored. This makes it possible to eliminate the information abnormality specified by the program monitoring unit 252 by using the configuration for eliminating the information abnormality at the start of supplying the operating power.

In the configuration in which whether or not the checksum is normal is monitored in the main process (FIG. 100) when the supply of operating power to the main CPU 63 is started, the checksum calculation target is for specific control. 221 and the stack area 222 for specific control are included, and the work area 223 for non-specific control and the stack area 224 for non-specific control are not included. As a result, it is possible to specify whether or not the information abnormality has occurred only in the storage area corresponding to the specific control in the main RAM 65.

When it is determined that the checksum is abnormal in the main process (FIG. 100) when the supply of the operating power to the main CPU 63 is started, the clear process at the time of non-setting update (step S6607) is executed. However, in the clear process at the time of non-setting update, the process of clearing “0” and the initial setting process are executed in the work area 221 for specific control and the stack area 222 for specific control. On the other hand, the process of clearing “0” is not executed in the work area 223 for non-specific control and the stack area 224 for non-specific control. As a result, it is possible to prevent the processing corresponding to the specific control from being continuously executed in the same state despite the occurrence of the information abnormality in the specific control work area 221 and the specific control stack area 222. In addition, the storage area corresponding to the non-specific control in the main RAM 65 is cleared to “0” when the information abnormality in the work area 221 for specific control and the stack area 222 for specific control is triggered. It becomes possible not to.

In the power failure information storage processing (FIG. 101) during power failure processing (steps S6709 to S6712), checksums are calculated for the specific control work area 221 and the specific control stack area 222, whereas the main RAM 65 The checksum is not calculated for the storage area corresponding to the non-specific control of. This makes it possible to prevent the processing period required to complete the power failure process from becoming excessively long.

When the occurrence of an abnormality is specified in the information stored in the work area 223 for non-specific control in another monitoring process (FIG. 107) executed in the process corresponding to non-specific control, the non-specific control is performed. In the separate monitoring process (FIG. 107) which is the process to be performed, the work area 223 for non-specific control is cleared to “0” and the initial setting process is executed. As a result, the processing corresponding to the non-specific control is executed in a state where the information of the work area 223 for non-specific control is retained as it is, although some abnormality has occurred in the work area 223 for non-specific control. It is possible to prevent it. Further, since the process of clearing the work area 223 for non-specific control to “0” and the process of initial setting are executed in the process corresponding to the non-specific control, the information of the work area 223 for non-specific control is updated. It is possible to prevent the processing corresponding to the specific control from intervening.

In another monitoring process (FIG. 107) that is a process corresponding to non-specific control, whether or not an abnormality has occurred in the work area 223 for non-specific control is executed, and Performs a process of clearing the work area 223 for non-specific control to “0” and a process of initial setting. As a result, a series of processes in the process corresponding to the non-specific control include monitoring whether or not an abnormality has occurred in the non-specific control work area 223 and executing initialization of the non-specific control work area 223. Can be executed as.

When the occurrence of an abnormality is specified in the information stored in the work area 223 for non-specific control in another monitoring process (FIG. 107) executed in the process corresponding to the non-specific control, The process of clearing "0" and the process of initializing the work area 223 are executed, but the process of clearing "0" and the process of initializing the stack area 224 for non-specific control are not executed. As a result, it is possible to eliminate the information abnormality in the work area 223 for non-specific control, and the information and the separate management of various registers used in the process corresponding to the specific control saved in the stack area 224 for non-specific control. It is possible to prevent the information at the return address from being deleted after the processing is completed.

The process of clearing the work area 221 for the specific control and the stack area 222 for the specific control to “0” and initializing the work area is executed by the process corresponding to the specific control, and the work area 223 for the non-specific control is set to “0”. The process of clearing and initializing is executed by the process corresponding to the non-specific control. As a result, also with respect to such initialization processing, the work area 221 for specific control and the stack area 222 for specific control are treated as dedicated storage areas for processing corresponding to specific control, and also for non-specific control. The work area 223 can be treated as a dedicated storage area for processing corresponding to non-specific control.

In the main process (FIG. 100), it is configured to monitor whether the set values are normal in steps S6608 and S6614. However, the process of monitoring whether the set values are normal is performed. The configuration may not be executed. This makes it possible to reduce the processing load of the processing at the start of the supply of the operating power, which is executed when the supply of the operating power to the main CPU 63 is started. In addition, even if the process at the start of supplying the operating power does not monitor whether or not the set value is normal, a timer interrupt executed after the process at the start of supplying the operating power is completed. Since the setting monitoring process (step S6820) of the process (FIG. 103) monitors whether or not the set value is normal, it is possible to cope with the abnormal set value.

The setting monitoring process (step S6820) is not limited to the configuration executed every time the timer interrupt process (FIG. 103) is activated. The configuration may be configured such that the setting monitoring process (step S6820) is performed every time the process is performed a number of times (for example, 10,000 times). In this case, it is possible to suppress the frequency of execution of the monitoring while regularly monitoring whether or not the set value is normal.

Further, the setting monitoring process (step S6820) may be configured to be executed by the residual process (steps S6610 to S6613) in the main process (FIG. 100). In this case, it becomes possible to monitor whether or not the set value is normal by utilizing the free time in the situation where the timer interrupt process is not executed.

Further, the setting monitoring process (step S6820) may be executed when the game time is newly started. More specifically, the setting monitoring process (step S6820) may be executed before the hit determination process is executed when the game time is newly started. As a result, it is possible to prevent the success/failure determination process from being executed when the set value is abnormal.

Further, when it is specified that the set value is abnormal in the setting monitoring process (step S6820), the work is provided in the work area 221 for specific control instead of the configuration of shifting to the set value updating process (step S6904). The game stop flag may be set to "1". In this case, since a positive determination is made in step S6807 in the timer interrupt process (FIG. 103), the processes in steps S6808 to S6821 are not executed, and thus the progress of the game is stopped if the set value is abnormal. Becomes However, since the processes of steps S6801 to S6806 are executed, power failure monitoring is executed, and the winning random number counter C1, the big hit type counter C2, the reach random number counter C3, and the random number initial value counter CINI are updated, and Fraud detection is performed. In addition, when the game stop flag is set to "1", a notification indicating that the set value should be updated may be executed to prompt execution of the set value update process. In this case, the game hall administrator who confirms the notification performs a power-on operation in a mode in which the setting value update processing is executed after performing a power-off operation, thereby clearing the game stop flag to "0". Then, the state in which the progress of the game is stopped is released, and the set value updating process is executed to set the normal set value.

When it is determined that the setting value is abnormal in the setting monitoring process (step S6820), the main process (1) is set in the setting abnormality flag provided in the work area 221 for specific control. (FIG. 100) may be started, and in order to stop the progress of the game with the setting abnormality flag set to “1” and to release the state where the progress of the game is stopped, the power is turned off. It may be configured to require ON. In this case, in the main process (FIG. 100), even if the operation for executing the set value update process is not performed, if the setting error flag is set to "1", the setting is forcibly set. By executing the value update process, it becomes possible to force the new setting of the set value by using the set value update process set in the main process (FIG. 100).

Further, when the program monitoring unit 252 identifies the occurrence of the information abnormality and the reset signal is forcibly turned from OFF to ON, the initialization processing is performed on the work area 221 for specific control. The setting value of the pachinko machine 10 may be “setting 1”. When the program monitoring unit 252 identifies the occurrence of the information abnormality and the reset signal is forcibly turned from OFF to ON, the setting is performed after the initialization process is executed for the specific control work area 221. The value update process may be executed.

Further, when the program monitoring unit 252 identifies the occurrence of the information abnormality, the reset signal is not compulsorily turned from OFF to ON, and the clear process at the time of non-setting update (step S6607) is executed. Alternatively, the configuration may be such that the clear process (step S6620) and the set value update process (step S6621) at the time of setting update are executed.

Further, in the clearing process at the time of non-setting update (step S6607), the setting value of the pachinko machine 10 becomes "setting 1" by initializing the storage area for storing the setting value information in the work area 221 for specific control. The configuration may be used, or the configuration may be a preset setting value other than “setting 1”. As a result, when the clearing process at the time of non-setting update is executed, it becomes possible to set the preset value.

Further, in the clearing process at the time of non-setting update (step S6607), the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to "0", but may be cleared to "0". Good.

Although the management start flag is not cleared to "0" in step S7204 in the separate monitoring process (Fig. 107), the management start flag may be cleared to "0". Further, in step S7204 of the separate monitoring process (FIG. 107), the normal counter area 231, the open/close execution mode counter area 232, and the high frequency support mode counter area 233 may not be cleared to “0”. The configuration may be such that 234 is not cleared to "0".

In step S7204 of the separate monitoring process (FIG. 107), the process of clearing “0” and the initial setting process are performed not only on the work area 223 for non-specific control but also on the stack area 224 for non-specific control. It may be configured. In this case, in the stack area 224 for non-specific control, it is used in the information corresponding to the return address of the management execution process after the completion of the separate monitoring process and the process corresponding to the specific control saved in the stack area 224 for non-specific control. It is preferable not to erase the information in the various registers.

In another monitoring process (FIG. 107), whether or not an abnormality has occurred in the stack area 224 for non-specific control is checked. The stack area 224 may be configured to execute the process of clearing “0” and the initial setting process. In this case, it is preferable not to erase the information of the return address of the management execution process after the end of the separate monitoring process in the stack area 224 for non-specific control.

Further, both the specific control work area 221 and the specific control stack area 222 are not limited to the configuration in which the checksum is calculated, and only the specific control work area 221 is the checksum calculation target. Alternatively, the check area may be calculated only in the stack area 222 for specific control.

<31st Embodiment>
In this embodiment, the processing configuration of the main processing executed by the main CPU 63 is different from that in the thirtieth embodiment. The configuration different from that of the thirtieth embodiment will be described below. The description of the same configuration as that of the thirtieth embodiment is basically omitted.

FIG. 108 is a flowchart showing the main processing executed in the main CPU 63 in this embodiment. The processes of steps S7301 to S7322 in the main process are executed by using the specific control program and the specific control data in the main CPU 63.

First, power-on wait processing is executed (step S7301). In the power-on wait process, for example, the main process is started and waits for a predetermined time for waiting (specifically, 1 second) without proceeding to the next process. During the execution period of the power-on weight process, the operation start and initial setting of the symbol display device 41 are completed. After that, access to the main RAM 65 is permitted (step S7302).

After that, it is determined whether or not the power failure flag provided in the work area 221 for specific control in the main RAM 65 is set to "1" (step S7303). If the power failure flag is set to "1" (step S7303: YES), checksums are calculated for the specific control work area 221 and the specific control stack area 222 (step S7304). The checksum calculation method is the same as step S6604 of the main process (FIG. 100) in the thirtieth embodiment.

After that, the specific control work area 221 and the specific control work area 221 which are calculated and stored in the specific control work area 221 in the power failure process executed immediately before the supply of the operating power to the main CPU 63 is stopped. The checksum for the stack area 222 is read from the work area 221 for specific control, and the read checksum is compared with the checksum calculated in step S7304 (step S7305). Then, it is determined whether the checksums match each other (step S7306).

When a positive determination is made in step S7306, the processes of steps S7307 to S7320 are executed. In this case, the processing contents of steps S7307 to S7314 are the same as steps S6614 to S6621 of the main processing (FIG. 100) in the thirtieth embodiment, and steps S7316 to S7320 are main in the thirtieth embodiment. This is the same as steps S6609 to S6613 of the processing (FIG. 100).

Further, when the reset button 68c is pressed (step S7308: YES), if a negative determination is made in any of steps S7309 to S7311, a clear process at the time of non-setting update is executed (step). S7315). The processing content of the clear processing at the time of non-setting update is the same as step S6607 of the main processing (FIG. 100) in the thirtieth embodiment. However, in the present embodiment, after executing the clear process at the time of non-setting update, the process proceeds to steps S7316 to S7320 without determining whether or not the set value is normal. The clear process at the time of non-setting update (step S7315) is executed only when a negative determination is made in any of steps S7309 to S7311, but before the processes of steps S7309 to S7311 are executed. Since it is determined in step S7307 whether or not the set value is normal, it is not necessary to determine whether or not the set value is normal after executing the clear processing at the time of non-setting update.

If a negative determination is made in step S7303 or step S7306, that is, if the power failure flag in the specific control work area 221 is not set to "1" or a checksum error occurs, the clear processing at the time of error is executed. Yes (step S7321). FIG. 109 is a flow chart showing the clearing process at the time of abnormality. Note that the processes of steps S7401 to S7405 in the abnormal clearing process are executed by the main CPU 63 using the specific control program and the specific control data.

First, the clear processing of the work area 221 for specific control is executed (step S7401). In the clear processing, the specific control work area is excluded except for the area (specifically, the set value counter) in which the setting value information indicating the setting state of the pachinko machine 10 is set in the specific control work area 221. 221 is cleared to “0” and the area for which the “0” is cleared is initialized. As a result, the area indicating whether or not the winning/winning lottery mode is the high-probability mode is cleared to "0". The mode is a low probability mode. In addition, the game times are not being executed, the opening/closing execution mode is not being executed, and the general-purpose display unit 38a is not being variably displayed, and the general electric accessory 34a is in the closed state. It becomes a situation. Further, since the hold storage area 65a and the universal electric power reserve area 65c provided in the work area 221 for specific control are also cleared to "0", the reserved information for the special figure display section 37a is deleted and the general figure display section is deleted. The hold information for 38a is deleted.

After that, the clearing process of the stack area 222 for specific control is executed (step S7402). In the clearing process, the stack area 222 for specific control is cleared to "0" and is initialized.

After that, as "PUSH PSW", the information in the flag register of the main CPU 63 is saved in the stack area 222 for specific control by a push command (step S7403). The flag register includes a carry flag, a zero flag, a P/V flag, a sine flag, a half carry flag, etc., and the information in the flag register changes depending on the execution result of an arithmetic instruction, a rotate instruction, an input/output instruction, and the like. By saving the information in the flag register before the program of the subroutine corresponding to the clear processing for non-specific control is started, the flag in the state before the call of the subroutine or the state before the change after the subroutine is started It becomes possible to save the information of the register in the stack area 222 for specific control. The information amount of the flag register is 1 byte.

After that, by reading the program of the subroutine corresponding to the non-specific control clear processing set in the non-specific control program, the non-specific control clear processing is started (step S7404). In this case, the information for specifying the return address of the clear processing at the time of abnormality after the execution of the clear processing for non-specific control is written in the stack area 222 for specific control by the push command. When the clear processing for non-specific control is completed, the pop instruction reads the information for specifying the return address, and the program returns to the program for the clear processing at the time of abnormality indicated by the return address.

When returning to the program for the clear processing at the time of abnormality after executing the clear processing for non-specific control, the flag register saved in the stack area 222 for specific control in step S7402 as a "POP PSW" by a pop command. Information is returned to the flag register of the main CPU 63 (step S7405). As a result, the information in the flag register of the main CPU 63 is restored to the information at the time when step S7402 was executed. That is, the information in the flag register of the main CPU 63 is restored to the information for executing the specific control.

FIG. 110 is a flowchart showing the clearing process for non-specific control. The processes of steps S7501 to S7516 in the non-specific control clearing process are executed by the main CPU 63 using the non-specific control program and the non-specific control data.

First, as "LDSP, Y(u+2)", a load instruction sets Y(u+2) as a fixed address at the start of the non-specific control in the stack pointer of the main CPU 63 (step S7501). In this case, as in step S3901 of the management execution process (FIG. 71) in the fifteenth embodiment, information on the last address in the stack area 224 for non-specific control is set in the stack pointer.

After that, the information of the WA register of the main CPU 63 is saved to the WA buffer set in the work area 223 for non-specific control by a load instruction as "LD (_WABUF), WA" (step S7502). Further, as "LD (_BCBUF), BC", the load instruction saves the information of the BC register of the main CPU 63 to the BC buffer set in the work area 223 for non-specific control (step S7503). Also, "LD
(_DEBUF), DE”, the load instruction saves the information in the DE register of the main CPU 63 to the DE buffer set in the work area 223 for non-specific control (step S7504). Further, as "LD (_HLBUF), HL", the load instruction saves the information in the HL register of the main CPU 63 to the HL buffer set in the work area 223 for non-specific control (step S7505). Further, as "LD (_IXBUF), IX", the load instruction saves the information in the IX register of the main CPU 63 to the IX buffer set in the work area 223 for non-specific control (step S7506). Further, as "LD (_IYBUF), IY", the information of the IY register of the main CPU 63 is saved in the IY buffer set in the work area 223 for non-specific control by a load instruction (step S7507).

In addition to the flag register already described, various general-purpose registers, auxiliary registers, and index registers exist in the registers of the main CPU 63. In this case, in steps S7502 to S7507, each information of the WA register, the BC register, the DE register, the HL register, the IX register, and the IY register, which are some of the various general-purpose registers, auxiliary registers, and index registers. Are saved in the corresponding buffer in the work area 223 for non-specific control. The WA register, the BC register, the DE register, the HL register, the IX register, and the IY register each have an information amount of 2 bytes.

These WA register, BC register, DE register, HL register, IX register, and IY register are processes corresponding to non-specific control, partly clearing the work area 223 for non-specific control (step S7508) and initial setting process ( This is a register used in step S7509). The information set in such a register is saved in the non-specific control work area 223 prior to the execution of the partial clearing process (step S7508) and the initial setting process (step S7509) of the non-specific control work area 223. By doing so, it becomes possible to save the information of these registers used in the specific control before the non-specific control is started. Therefore, even if these registers are overwritten in the non-specific control, the information saved in the work area 223 for the non-specific control is restored to these registers when the non-specific control is finished, so that the states of these registers can be restored. Can be returned to the state corresponding to the specific control before the non-specific control is executed.

Further, instead of saving all information of various general-purpose registers, auxiliary registers, and index registers in the work area 223 for non-specific control, the work area 223 for non-specific control, which is a process corresponding to non-specific control, is stored. Information for the WA register, BC register, DE register, HL register, IX register, and IY register that is the target of use in the partial clear processing (step S7508) and the initial setting processing (step S7509) is selectively used for non-specific control. By saving the information in the register in the work area 223 for non-specific control by saving it in the work area 223, it is possible to suppress the capacity secured. Therefore, while securing a large capacity of the work area 223 for non-specific control that can be used in the process of partially clearing the work area 223 for non-specific control (step S7508) and the initialization process (step S7509), It becomes possible to save the information in the register as described above. Of course, various general-purpose registers, auxiliary registers, and index registers in the main CPU 63 other than the WA register, BC register, DE register, HL register, IX register, and IY register are compatible with non-specific control. The information set before the processing to be performed is stored and held until the processing corresponding to the non-specific control ends and the processing corresponding to the specific control is restarted.

Further, the register information is not saved in the non-specific control stack area 224 but is saved in the non-specific control work area 223, so that the capacity of the non-specific control stack area 224 can be reduced to that extent. It will be possible. Further, when the stack area 224 for non-specific control is used, the writing order of information is read first from the later information as described above. Therefore, the reading order of information is displaced due to some noise or the like. If this happens, all subsequent read order information will be restored to a different register. The probability of occurrence of such an event increases as the amount of information saved in the stack area 224 for non-specific control increases. On the other hand, by saving the information in the register in the work area 223 for non-specific control, it is possible to prevent the above event from occurring even when there is a large amount of information to be saved. ..

After performing the processes of steps S7502 to S7507, a process of partially clearing the work area 223 for non-specific control is performed (step S7508). In the partial clear processing, among the storage areas of the work area 223 for non-specific control, storage areas other than the storage area in which the information of the various registers of the main CPU 63 used in the processing corresponding to the specific control is saved. Is cleared to "0". Specifically, among the storage areas of the work area 223 for non-specific control, the WA buffer, BC buffer, DE buffer, HL buffer, IX buffer, and IY buffer are not cleared to "0", while storage other than these various buffers is not performed. Clear the area to "0".

In this case, all of the normal counter area 231, the open/close execution mode counter area 232, the high frequency support mode counter area 233, the calculation result storage area 234, and the management start flag are cleared to “0”. This makes it possible to eliminate the information abnormality in the work area 223 for non-specific control. In addition, the processing corresponding to the non-specific control ends by not clearing the storage area in which the information of the various registers of the main CPU 63 used in the processing corresponding to the specific control is saved. When returning to the process corresponding to the specific control, it becomes possible to return the information used in the process corresponding to the specific control to the various registers of the main CPU 63.

Also, in step S7508, the stack area 224 for non-specific control is not cleared to "0". The stack area 224 for non-specific control stores the return address information of the clear processing (FIG. 109) at the time of abnormality after the completion of the clear processing for non-specific control. By not clearing "0" in 224, it is possible to prevent the information at the return address from being erased.

After that, initialization processing is executed (step S7509). In the initial setting process, the initial setting is performed for the storage area for which “0” is cleared in the work area 223 for non-specific control in step S7508.

After that, as “LD SP, Y(r+α)”, the load instruction causes the stack pointer of the main CPU 63 to return to the specific control, as in step S3909 of the management execution process (FIG. 71) in the fifteenth embodiment. Y(r+α) is set as the fixed address at the time (step S7510). The address of Y(r+α) is set as an address between Y(r+8) and Y(s) in the stack area 222 for specific control.

After that, the information saved in the WA buffer of the work area 223 for non-specific control is overwritten in the WA register of the main CPU 63 by the load instruction as "LD WA, (_WABUF)" (step S7511). Further, as "LD BC, (_BCBUF)", the information saved in the BC buffer of the work area 223 for non-specific control is overwritten in the BC register of the main CPU 63 by the load instruction (step S7512). Further, the information saved in the DE buffer of the work area 223 for non-specific control is overwritten in the DE register of the main CPU 63 by the load instruction as "LD DE, (_DEBUF)" (step S7513). Further, as "LD HL,(_HLBUF)", the load instruction overwrites the information saved in the HL buffer of the work area 223 for non-specific control in the HL register of the main CPU 63 (step S7514). Further, the information saved in the IX buffer of the work area 223 for non-specific control is overwritten in the IX register of the main CPU 63 by the load instruction as "LD IX, (_IXBUF)" (step S7515). In addition, the information saved in the IY buffer of the work area 223 for non-specific control is overwritten in the IY register of the main CPU 63 by a load instruction as "LDIY, (_IYBUF)" (step S7516). By performing the processing of steps S7511 to S7516, processing corresponding to non-specific control is started for each information of the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63. It is possible to restore the information corresponding to the specific control immediately before.

According to the above configuration, when the power failure flag is not set to “1” in the main process (FIG. 108) executed when the supply of the operating power to the main CPU 63 is started, or the checksum is abnormal. In some cases, not only the work area 221 for specific control and the stack area 222 for specific control but also the work area 223 for non-specific control is set to "0" by executing the clear processing at the time of abnormality (step S7321). It is cleared and initialized. When the information abnormality occurs in the work area 221 for specific control, the work area 223 for non-specific control may also have information abnormality. The work area 223 is also initialized so that the processing corresponding to the non-specific control is not executed as it is even though the work area 223 for non-specific control has an information abnormality. It becomes possible to do.

Even when the process of clearing "0" and the process of initializing the work area 223 for non-specific control are executed in the clear processing (step S7321) at the time of abnormality, the work area for non-specific control is executed. The information of various registers used in the process corresponding to the specific control saved in 223 is not cleared to "0". As a result, a process of clearing "0" to the work area 223 for non-specific control while preventing the information used in the process corresponding to the specific control from ending after the process corresponding to the non-specific control is completed. Also, it becomes possible to execute processing for initial setting.

Even when the process of clearing “0” and the process of initializing the work area 223 for non-specific control are executed in the clear processing (step S7321) at the time of abnormality, the stack area 224 for non-specific control is executed. For 0, the process of clearing “0” and the process of initial setting are not executed. This makes it possible to prevent the information of the return address from being erased after the clear processing for non-specific control (FIG. 110) is completed.

The process of clearing “0” and the process of initializing the work area 221 for specific control and the stack area 222 for specific control are executed by the process corresponding to the specific control, and the work area 223 for non-specific control is The process of clearing “0” and the process of initial setting are executed in the process corresponding to the non-specific control. As a result, with respect to the process of clearing “0” and the process of initial setting, the work area 221 for specific control and the stack area 222 for specific control are treated as a dedicated storage area for the process corresponding to the specific control, and The work area 223 for specific control can be treated as a dedicated storage area for processing corresponding to non-specific control.

Note that both the specific control work area 221 and the specific control stack area 222 are not limited to the configuration in which the checksum is calculated, and only the specific control work area 221 is the checksum calculation target. Alternatively, the check area may be calculated only in the stack area 222 for specific control.

Alternatively, the work area 223 for non-specific control may be a checksum calculation target. In this case, the work area 221 for specific control and the work area 223 for non-specific control may be the target of checksum calculation, and the stack area 222 for specific control and the work area 223 for non-specific control may be checked. The calculation target of the sum may be used, or the work area 221 for specific control, the stack area 222 for specific control, and the work area 223 for non-specific control may be used for checksum calculation.

Further, the stack area 224 for non-specific control may be the target of checksum calculation. In this case, the work area 221 for specific control and the stack area 224 for non-specific control may be the target of checksum calculation, and the stack area 222 for specific control and the stack area 224 for non-specific control may be checked. The sum may be calculated, or the work area 221 for specific control, the stack area 222 for specific control, and the stack area 224 for non-specific control may be calculated as checksums.

Further, the work area 223 for non-specific control and the stack area 224 for non-specific control may be the target of checksum calculation. In this case, the work area 221 for specific control, the work area 223 for non-specific control, and the stack area 224 for non-specific control may be the target of checksum calculation. The work area 223 for specific control and the stack area 224 for non-specific control may be the target of checksum calculation, and the work area 221, the stack area 222 for specific control, and the stack area 222 for non-specific control may be used. The work area 223 and the non-specific control stack area 224 may be the target of checksum calculation.

Further, in step S7508 and step S7509 in the clear processing for non-specific control (FIG. 110), not only the work area 223 for non-specific control but also the stack area 224 for non-specific control is cleared to "0". It may be configured to execute the initial setting process. In this case, it is preferable not to erase the information of the return address of the clear processing at the time of abnormality after the completion of the clear processing for non-specific control.

Further, in step S7508 in the clear processing for non-specific control (FIG. 110), the management start flag is cleared to “0”, but the management start flag may not be cleared to “0”. Further, in step S7508 in the clear processing for non-specific control (FIG. 110), the normal counter area 231, the open/close execution mode counter area 232, and the high frequency support mode counter area 233 may not be cleared to “0”. The calculation result storage area 234 may not be cleared to "0".

<Thirty-second embodiment>
The present embodiment is different from the thirtieth embodiment in the processing configuration relating to the information abnormality monitoring of the main RAM 65 using the checksum. The configuration different from that of the thirtieth embodiment will be described below. The description of the same configuration as that of the thirtieth embodiment is basically omitted.

FIG. 111 is a flowchart showing a power failure information storage process in this embodiment executed by the main CPU 63. The power failure information storage process is executed in step S6801 in the timer interrupt process (FIG. 103). Further, the processing of steps S7601 to S7613 in the power failure information storage processing is executed by the main CPU 63 using the specific control program and the specific control data.

In steps S7601 to S7608 in the power failure information storage process, the same processes as steps S6701 to S6708 of the power failure information storage process (FIG. 101) in the thirtieth embodiment are executed. When the occurrence of a power failure is specified, an affirmative decision is made in step S7608 and the processing during a power failure in steps S7609 to S7613 is executed.

Specifically, first, the power failure flag provided in the specific control work area 221 is set to "1" (step S7609). As a result, when the power failure process is executed normally and the information storage and holding in the main RAM 65 is normally performed, the power supply for operation to the main CPU 63 is restarted, the specific control is performed. The power failure flag of the work area 221 of 1 is set to "1".

After that, checksums are calculated for the specific control work area 221 and the specific control stack area 222 (step S7610). In this case, the storage areas in the specific control work area 221 and the specific control stack area 222, which are to be calculated when the specific control checksum is calculated, are stored in the checksum monitoring process (FIG. 112) described later in step S7701. Is the same as the storage area in the work area 221 for specific control and the stack area 222 for specific control, which is the target of the checksum calculation for specific control. Further, in the storage area to be calculated when calculating the checksum for the specific control, an area (specifically, a set value information indicating the setting state of the pachinko machine 10 in the specific control work area 221 is set). Is a set value counter). Then, the calculated checksum for specific control is a storage area for storing the checksum for specific control in the work area 221 for specific control, and is excluded from the calculation target of the checksum for specific control. It is stored in the existing memory area.

After that, checksums are calculated for the work area 223 for non-specific control and the stack area 224 for non-specific control (step S7611). In this case, the storage areas in the non-specific control work area 223 and the non-specific control stack area 224 that are to be calculated when calculating the non-specific control checksum are the checksum monitoring processing described later (FIG. 112). In step S7706, the storage area is the same as the storage area in the non-specific control work area 223 and the non-specific control stack area 224 for which the non-specific control checksum is calculated. Then, the calculated checksum for non-specific control is a storage area for storing the checksum for non-specific control in the work area 221 for specific control, and is excluded from the calculation target of the checksum for specific control. Stored in the designated storage area.

After that, all the output port information in the register of the main CPU 63 is set to "0" (step S7612), and access to the main RAM 65 is prohibited (step S7613). Then, the infinite loop is continued until the power is completely cut off and the processing cannot be executed.

Next, the checksum monitoring process executed by the main CPU 63 will be described with reference to the flowchart of FIG. The checksum monitoring process is executed instead of steps S6604 to S6606 in the main process (FIG. 100). Further, the processes of steps S7701 to S7711 in the checksum monitoring process are executed by the main CPU 63 using the specific control program and the specific control data.

First, a checksum for specific control is calculated for the specific control work area 221 and the specific control stack area 222 (step S7701). The method of calculating the checksum for the specific control is the same as step S7610 in the power failure information storage processing (FIG. 111). After that, the checksum for the specific control calculated in step S7610 of the power failure process executed immediately before the supply of the operating power to the main CPU 63 is stopped and specified in the work area 221 for the specific control is specified. The checksum for specific control read out from the control work area 221 is compared with the checksum for specific control calculated in step S7701 (step S7702). Then, it is determined whether or not the checksums for the specific control match (step S7703).

If the checksums for specific control do not match (step S7703: NO). The clear processing of the work area 221 for specific control is executed (step S7704). In the clear processing, the specific control work area is excluded except for the area (specifically, the set value counter) in which the setting value information indicating the setting state of the pachinko machine 10 is set in the specific control work area 221. 221 is cleared to “0” and the initial setting is executed. As a result, the area indicating whether or not the winning/winning lottery mode is the high-probability mode is cleared to "0". The mode is a low probability mode. In addition, the game times are not being executed, the opening/closing execution mode is not being executed, and the general-purpose display unit 38a is not being variably displayed, and the general electric accessory 34a is in the closed state. It becomes a situation. Further, since the hold storage area 65a and the universal electric power reserve area 65c provided in the work area 221 for specific control are also cleared to "0", the reserved information for the special figure display section 37a is deleted and the general figure display section is deleted. The hold information for 38a is deleted. In the clearing process, various registers of the main CPU 63 are cleared to "0" and then the initial setting is executed. Further, the stack area 222 for specific control is cleared to "0" and the initial setting is executed (step S7705).

If an affirmative decision is made in step S7703, or if the processing of step S7705 is executed, a checksum for non-specific control is calculated for the work area 223 for non-specific control and the stack area 224 for non-specific control (step S7706). The method for calculating the checksum for the non-specific control is the same as step S7611 in the power failure information storage process (FIG. 111). After that, the checksum for the non-specific control calculated in step S7611 of the power failure process executed immediately before the supply of the operating power to the main CPU 63 is saved and stored in the work area 221 for the specific control is performed. While reading from the work area 221 for specific control, the read checksum for nonspecific control is compared with the checksum for nonspecific control calculated in step S7706 (step S7707). Then, it is determined whether or not the checksums for non-specific control match (step S7708).

If the checksums for non-specific control do not match (step S7708: NO), the information in the flag register of the main CPU 63 is saved in the stack area 222 for specific control by a push command as "PUSH PSW" ( Step S7709). The flag register includes a carry flag, a zero flag, a P/V flag, a sine flag, a half carry flag, etc., and the information in the flag register changes depending on the execution result of an arithmetic instruction, a rotate instruction, an input/output instruction, and the like. By saving the information in the flag register before the program of the subroutine corresponding to the clear processing for non-specific control is started, the flag in the state before the call of the subroutine or the state before the change after the subroutine is started It becomes possible to save the information of the register in the stack area 222 for specific control. The information amount of the flag register is 1 byte.

After that, by reading the program of the subroutine corresponding to the clear processing for non-specific control set in the program for non-specific control, the clear processing for non-specific control is started (step S7710). In this case, information for specifying the return address of the checksum monitoring process after the execution of the non-specific control clearing process is written in the specific control stack area 222 by the push command. When the clear processing for non-specific control is completed, the pop instruction reads the information for specifying the return address, and the program returns to the checksum monitoring program indicated by the return address.

When the program returns to the clearing process at the time of abnormality after the execution of the clearing process for non-specific control, the flag register saved in the stack area 222 for specific control in step S7709 as a "POP PSW" by the pop command. Information is returned to the flag register of the main CPU 63 (step S7711). As a result, the information in the flag register of the main CPU 63 is restored to the information at the time when step S7709 was executed. That is, the information in the flag register of the main CPU 63 is restored to the information for executing the specific control.

FIG. 113 is a flowchart showing the clearing process for non-specific control. The processes of steps S7801 to S7818 in the non-specific control clearing process are executed by the main CPU 63 using the non-specific control program and the non-specific control data.

In steps S7801 to S7807 in the non-specific control clear processing, the same processing as steps S7501 to S7507 in the non-specific control clear processing (FIG. 110) in the thirty-first embodiment is executed.

After that, a part of the non-specific control work area 223 is cleared (step S7808). In the partial clear processing, among the storage areas of the work area 223 for non-specific control, storage areas other than the storage area in which the information of the various registers of the main CPU 63 used in the processing corresponding to the specific control is saved. Is cleared to "0". Specifically, among the storage areas of the work area 223 for non-specific control, the WA buffer, BC buffer, DE buffer, HL buffer, IX buffer, and IY buffer are not cleared to "0", while storage other than these various buffers is not performed. Clear the area to "0".

In this case, all of the normal counter area 231, the open/close execution mode counter area 232, the high frequency support mode counter area 233, the calculation result storage area 234, and the management start flag are cleared to “0”. This makes it possible to eliminate the information abnormality in the work area 223 for non-specific control. In addition, the processing corresponding to the non-specific control ends by not clearing the storage area in which the information of the various registers of the main CPU 63 used in the processing corresponding to the specific control is saved. When returning to the process corresponding to the specific control, it becomes possible to return the information used in the process corresponding to the specific control to the various registers of the main CPU 63.

After that, initialization processing is executed (step S7809). In the initial setting process, the initial setting is performed for the storage area for which “0” is cleared in step S7808 in the work area 223 for non-specific control.

After that, a partial clearing process of the stack area 224 for non-specific control is executed (step S7810). In the partial clearing process, information on the return address of the checksum monitoring process (FIG. 112) after the completion of the clearing process for non-specific control is stored in each storage area of the stack area 224 for non-specific control. The storage areas other than the specified storage area are cleared to "0". This prevents the information at the return address of the checksum monitoring process (FIG. 112) after the completion of the non-specific control clearing process from being erased, while preventing the information error in the non-specific control stack area 224. Can be eliminated.

After that, the initial setting process is executed (step S7811). In the initial setting process, the initial setting is performed for the storage area for which the “0” is cleared in step S7810 in the stack area 224 for non-specific control.

Then, the processes of steps S7812 to S7818 are executed. The processing in these steps S7812 to S7818 is the same as the processing in steps S7510 to S7516 in the non-specific control clear processing (FIG. 110) in the thirty-first embodiment.

According to the above configuration, the checksum for the specific control work area 221 and the specific control stack area 222 and the checksum for the non-specific control work area 223 and the non-specific control stack area 224 are provided. Calculated individually. This makes it possible to individually specify the information abnormality in each of the storage area of the main RAM 65 corresponding to the specific control and the storage area of the main RAM 65 corresponding to the non-specific control.

If the checksum for specific control has an abnormality, the processing for clearing "0" and the initialization process are executed for the work area 221 for specific control and the stack area 222 for specific control to perform the non-specific control. If the checksum is abnormal, the process of clearing “0” and the initialization process are executed for the work area 223 for non-specific control and the stack area 224 for non-specific control. As a result, it is possible to narrow down the target for executing the processing of clearing “0” and the initialization processing to the area in which the abnormality of the checksum is specified.

The process of clearing “0” and the process of initializing the work area 221 for specific control and the stack area 222 for specific control are executed by the process corresponding to the specific control, and the work area 223 for non-specific control is The process of clearing “0” and the process of initial setting are executed in the process corresponding to the non-specific control. As a result, regarding the processing of clearing “0” and the initialization processing, the work area 221 for specific control and the stack area 222 for specific control are treated as a dedicated storage area for the processing corresponding to the specific control, and non-specific The control work area 223 can be treated as a dedicated storage area for processing corresponding to non-specific control.

Although the management start flag is cleared to "0" in step S7808 in the clear processing for non-specific control (FIG. 113), the management start flag may not be cleared to "0". Further, in step S7808 in the clear processing for non-specific control (FIG. 113), the normal counter area 231, the opening/closing execution mode counter area 232, and the high frequency support mode counter area 233 may not be cleared to “0”. The calculation result storage area 234 may not be cleared to "0".

<Thirty-third embodiment>
In this embodiment, the processing configuration executed by the main CPU 63 is different from that of the fifteenth embodiment. Hereinafter, a configuration different from that of the fifteenth embodiment will be described. The description of the same configuration as the fifteenth embodiment is basically omitted.

FIG. 114 is a flowchart showing the main processing executed in the main CPU 63 in this embodiment. The processes of steps S7901 to S7924 in the main process are executed by using the program for specific control and the data for specific control in the main CPU 63.

First, power-on initialization processing is executed (step S7901). In the power-on initialization process, for example, a predetermined wait time (specifically, 1 second) elapses after the main process is started, and the process waits without proceeding to the next process. In the predetermined period for this weight, the operation start and initial setting of the symbol display device 41 are completed. Also, access to the main RAM 65 is permitted.

After that, an internal function register setting process is executed (step S7902). In the internal function register setting process, the interrupt period of the first timer interrupt process (FIG. 117), which is a process that is periodically interrupted and activated with respect to the main process, is the first interrupt period (specifically, 4 milliseconds). And the interrupt period of the second timer interrupt process (FIG. 123), which is a process that is activated by periodically interrupting the main process, is set to a second interrupt period that is shorter than the first interrupt period. (Specifically, it is set to 2 milliseconds).

That is, in the present embodiment, the timer interrupt processing includes the first timer interrupt processing and the second timer interrupt processing so that the interrupt cycle becomes relatively long and short. Both the first timer interrupt process and the second timer interrupt process are activated by interrupting the main process. Further, the second timer interrupt process is activated by interrupting the first timer interrupt process. On the other hand, the first timer interrupt process does not start by interrupting the second timer interrupt process. If both the first interrupt cycle and the second interrupt cycle have passed in a situation where neither the first timer interrupt process nor the second timer interrupt process is being executed, the second The timer interrupt processing is started first. In this respect, it can be said that the second timer interrupt process is a process activated prior to the first timer interrupt process.

In the internal function register setting process, the first interrupt cycle of the first timer interrupt process is set in a predetermined register of the main CPU 63, and the second interrupt cycle of the second timer interrupt process is set in a specific register of the main CPU 63. To do. Further, in the internal function register setting process, in addition to the setting of the first and second interrupt cycles, the setting process of the numerical range of various counters such as the numerical range of the hit random number counter C1 is executed.

After that, "1" is set to the startup processing flag provided in the specific control work area 221 (step S7903). The start-up processing flag indicates that the first timer interrupt process should be terminated without executing the various processes set in the first timer interrupt process even if the first timer interrupt process is activated. This is a flag for specifying by the main CPU 63. By setting the start-up processing flag to “1”, even if the first timer interrupt processing is activated, the various processes set in the first timer interrupt processing are not executed and the first timer interrupt processing is not executed. The timer interrupt processing will be ended.

After that, interrupt permission is set (step S7904). As a result, the first timer interrupt process (FIG. 117) is activated in the first interrupt period and the second timer interrupt process (FIG. 123) is activated in the second interrupt period. However, since "1" is set in the startup processing flag in step S7903, even if the first timer interrupt processing is activated, various processing set in the first timer interrupt processing is executed. Without this, the first timer interrupt processing is ended.

After that, it is determined whether or not the reset button 68c has been pressed (step S7905). That is, it is determined whether or not the power of the pachinko machine 10 is turned on while the reset button 68c is being pressed and the supply of operating power to the main CPU 63 is started. Here, in the present embodiment, the main control device 60 is provided with the setting key insertion portion 68a and the reset button 68c, but is not provided with the update button 68b. Further, the main control device 60 is provided with not the first to third notification display devices 69a to 69c but the first to fourth notification display devices 201 to 204 as in the eleventh embodiment.

When the reset button 68c has not been pressed (step S7905: NO), it is determined whether or not the power failure flag provided in the specific control work area 221 is set to "1" (step S7906). "1" is set to the power failure flag when the power failure information storage processing (step S8202) of the first timer interrupt processing (FIG. 117) described later executes the power failure processing. The power outage flag is a flag for the main CPU 63 to specify whether or not the power outage process was appropriately performed at the previous power off time.

When "1" is set in the power failure flag (step S7906: YES), checksums are calculated for the specific control work area 221 and the specific control stack area 222 (step S7907). The method of calculating the checksum is arbitrary, but the same calculation method as that used when the checksum is calculated in the power failure process in the power failure information storage process (step S8202) of the first timer interrupt process (FIG. 117) described later Has become a method. The checksum calculated in the power failure process is stored in the work area 221 for specific control. The storage area of the work area 221 for specific control in which the checksum is stored is used when calculating the checksum. It is excluded from the storage areas to be calculated.

That is, when the checksum is calculated, the storage areas to be calculated, which are some storage areas in the specific control work area 221 and the specific control stack area 222, are the calculation targets. In the storage area to be calculated, the checksum is calculated in the power outage process when the supply of the operating power to the MPU 62 is stopped, and then the supply of the operating power to the MPU 62 is restarted to execute the process of step S7907. Until that time, when the power supply such as the backup power to the work area 221 for specific control and the stack area 222 for specific control is continued, it is basically a storage area in which information is not rewritten. Therefore, the information of the work area 221 for specific control and the stack area 222 for specific control is not changed from the supply of the operation power to the MPU 62 to the restart of the supply of the operation power to the MPU 62. In this case, the checksums of the specific control work area 221 and the specific control stack area 222 are the same as immediately before the supply of the operating power to the MPU 62 is stopped. In addition, the storage area to be calculated when calculating the checksum is an area (specifically, a set value counter) in which information of set values indicating the set state of the pachinko machine 10 in the work area 221 for specific control is set. )It is included. The checksum calculation target does not include the work area 223 for non-specific control and the stack area 224 for non-specific control.

After that, the specific control work area 221 and the specific control work area 221 which are calculated and stored in the specific control work area 221 in the power failure process executed immediately before the supply of the operating power to the main CPU 63 is stopped. The checksum for the stack area 222 is read from the work area 221 for specific control, and the read checksum is compared with the checksum calculated in step S7907 (step S7908). Then, it is determined whether or not the checksums match (step S7909).

If a negative determination is made in step S7906 or step S7909, that is, if the power failure flag is not set to "1" or the checksums do not match, the game stop flag provided in the work area 221 for specific control Is set to "1" (step S7910). The game stop flag is a situation in which a positive determination is made in step S8207 and the processing of steps S8208 to S8221 is not executed in the first timer interrupt processing (FIG. 117) described later, that is, execution of processing for advancing the game is stopped. This is a flag for the main CPU 63 to specify whether or not the situation should be met. When the game stop flag is set to "1", an affirmative decision is made in step S8207 of the first timer interrupt process (FIG. 117) which will be described later, whereby the process of steps S8208 to S8221 is not executed. As a result, if the power failure flag is not set to "1" because the power failure process was not properly performed at the previous power shutdown, the game progress is stopped and the specific control is performed. If at least one of the work area 221 and the stack area 222 for specific control does not match the checksums due to the change in the storage state of information since the last power-off, the progress of the game is stopped. It will be in a state of being.

In this case, in the storage area to be calculated when the checksum is calculated, the area (specifically, the setting value information indicating the setting state of the pachinko machine 10 in the specific control work area 221 is set as described above). Setting value counter) is included. Therefore, if the set value abnormality occurs after the last power-off, the checksums do not match, and the progress of the game is stopped.

On the other hand, even if the game stop flag is set to "1", the processes of steps S8202 to S8206 in the first timer interrupt process (Fig. 117) are executed. Therefore, even if the progress of the game is stopped, power failure monitoring is executed, and the winning random number counter C1, the big hit type counter C2, the reach random number counter C3, and the random number initial value counter CINI are updated, and Fraud detection is performed.

After that, an abnormal command indicating that an abnormality has occurred with respect to the power failure flag or the checksum when the supply of the operating power is started is transmitted to the sound emission control device 81 (step S7911). Upon receiving the abnormal command, the sound emission control device 81 causes the display light emitting unit 53 to emit light in a manner corresponding to the information abnormality at the time of starting the supply of the operating power, and the speaker unit 54 "Please change the setting." Is output. Moreover, the character image "Please change the setting." is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are ended when the supply of operating power to the pachinko machine 10 is stopped. However, even if the supply of the operating power to the pachinko machine 10 is temporarily stopped, the above notification is given when the supply of the operating power to the pachinko machine 10 is restarted until the setting value update process (step S7918) is executed. It may be configured to continue.

The manager of the game hall, who has confirmed the above notification in the situation where the progress of the game is stopped, temporarily stops the supply of operating power to the pachinko machine 10 and then resumes the supply of operating power to the pachinko machine 10. In this case, an operation for executing the set value updating process (step S7918) is performed. This makes it possible to set a new setting value in the setting value update processing (step S7918) when an abnormality occurs in the power failure flag or the checksum at the start of supplying the operating power. ..

In particular, in the storage area to be calculated when calculating the checksum, an area (specifically, the set value) in which the setting value information indicating the setting state of the pachinko machine 10 in the specific control work area 221 is set as described above. Counter) is included, there is a possibility that the set value is abnormal if the checksum is abnormal. On the other hand, when an abnormality occurs with respect to the checksum as described above, the execution of the setting value update processing (step S7918) is prompted, so that the game is not played with the abnormal setting value. It becomes possible to do.

When the power failure flag is set to "1" and the checksum is normal (step S7906 and step S7909: YES), it is determined whether the setting key insertion unit 68a is turned on by using the setting key. Then, it is determined whether or not the front door frame 14 is open to the inner frame 13 and the gaming machine main body 12 is open to the outer frame 11 (step S7913). The front door opening sensor 95 is used to detect whether or not the front door frame 14 is opened with respect to the inner frame 13 as in the thirtieth embodiment, and the gaming machine main body 12 is detected with respect to the outer frame 11. The main body open sensor 96 is used to detect whether or not it is in the open state, as in the thirtieth embodiment. The setting key insertion portion 68a is turned on by using the setting key (step S7912: YES), the front door frame 14 is open to the inner frame 13, and the gaming machine main body is opened to the outer frame 11. If 12 is in the open state (step S7913: YES), the setting confirmation process is executed (step S7914). In the setting confirmation process, the current setting values of the pachinko machine 10 are confirmed on the first to fourth notification display devices 201 to 204 used for displaying various parameters that are the management results of the game history. A process for performing a display indicating that the situation is present and a display indicating the current setting value of the pachinko machine 10 is executed.

FIG. 115 is a flowchart showing the setting confirmation processing. The processing of steps S8001 to S8003 in the setting confirmation processing is executed by using the specific control program and the specific control data in the main CPU 63.

First, "1" is set to the setting confirmation display flag provided in the work area 221 for specific control (step S8001). The setting confirmation display flag is a flag for the main CPU 63 to specify that the current setting value of the pachinko machine 10 is being confirmed. By setting the setting confirmation display flag to "1", the corresponding display control is performed for the first to fourth notification display devices 201 to 204 in the second timer interrupt process (FIG. 123) described later. Be seen. Accordingly, on the first to fourth notification display devices 201 to 204, a display indicating that the current setting value of the pachinko machine 10 is being confirmed and a display indicating the current setting value of the pachinko machine 10 are displayed. Is done.

Then, it is determined whether or not the setting key insertion unit 68a has been turned off using the setting key (step S8002). In this case, it may be configured to determine whether the setting key inserting section 68a is switched from the ON state to the OFF state, or may be configured to determine whether the setting key inserting section 68a is in the OFF state. If the setting key insertion unit 68a has not been turned off (step S8002: NO), the process of step S8002 is repeated.

When the setting key insertion unit 68a is turned off (step S8002: YES), the setting confirmation display flag in the work area 221 for specific control is cleared to "0" (step S8003). Accordingly, on the first to fourth notification display devices 201 to 204, a display indicating that the current set value of the pachinko machine 10 is being confirmed and a display indicating the current set value of the pachinko machine 10 are displayed. The state in which is performed is released. In this case, the display indicating the management result of the game history is started on the first to fourth notification display devices 201 to 204.

As described above, in the present embodiment, the power of the pachinko machine 10 is turned on while the setting key insertion portion 68a is turned on by the setting key without pressing the reset button 68c, so that the operating power to the main CPU 63 is increased. In the situation where the supply of the start of the main process is started and the reset button 68c is not pressed and the setting key insertion portion 68a is turned on, the process of allowing the game to proceed in the main process is performed. The setting confirmation processing is executed in a situation before the execution, that is, the processing at the start of the supply of the operating power is being executed. As a result, it becomes possible to confirm the set value in a situation where the game is not being played.

Assuming that the setting value is confirmed in the situation where the game continues, for example, if the setting value is confirmed during the execution of the game times, the setting value is being confirmed. Therefore, there is a possibility that the switching to the open/close execution mode may occur. In this case, there is a possibility that the game ball cannot be fired toward the special electric prize winning device 32 even though the opening/closing execution mode is started. Further, if the set value is confirmed during the execution of the opening/closing execution mode, the opening/closing execution mode will proceed under the situation where the setting value is being confirmed. It may not be possible to shoot a game ball toward.

Assuming that the progress of the game is stopped when the setting value is confirmed, if the setting value confirmation is started in the situation where the game is being performed, the progress of the game is stopped midway. Processing may be complicated. For example, when the confirmation of the set value is started during the execution of the game time and the progress of the game is to be stopped midway, a process for stopping the game time is required. In this case, when the confirmation of the set value is started, the variable display of the symbol on the symbol display device 41 is stopped midway, and when the confirmation of the set value is completed, the variable display of the symbol on the symbol display device 41 is restarted. If so, complicated processing is required. In addition, for example, when the confirmation of the set value is started during the execution of the opening/closing execution mode and it is attempted to stop the progress of the game on the way, a process for stopping the opening/closing execution mode is required. Further, when the setting value confirmation is started during the execution of the variable display of the pattern on the public figure display unit 38a and the game progress is to be stopped midway, the process for stopping the variable display of the pattern is performed. Will be required. Further, if the setting value confirmation is started during the execution of the open execution state of the general electric auditors a and the progress of the game is to be stopped midway, a process for stopping the open execution state is required. Become. On the other hand, a configuration may be considered in which the setting value is confirmed by waiting until all the games are completed, but in this case, the game times, the opening/closing execution mode, the variable display of the pattern on the normal figure display portion 38a, and the normal electric combination Since it is necessary to wait until a state in which none of the open execution states of the object 34a is executed is executed, there is a possibility that the waiting time until the confirmation of the set value is started becomes long.

On the other hand, in the main process executed when the supply of the operating power to the main CPU 63 is started, when the supply of the operating power is the situation before the process that allows the progress of the game is executed. Since the setting confirmation processing is executed in the situation where the processing is being executed, the setting value is confirmed in the situation where the progress of the game is already stopped. As a result, it is possible to prevent the setting value from being confirmed while the game is in progress, and to stop the progress of the game midway when confirming the set value, or to stop the progress of the game. There is no need to wait for confirmation of the set value until Therefore, it becomes possible to properly confirm the set value.

Returning to the description of the main process (FIG. 114), when the reset button 68c is pressed (step S7905: YES), the RAM clear process is executed (step S7915). In the RAM clearing process, the work area for specific control except for the area (specifically, the set value counter) in which the setting value information indicating the setting state of the pachinko machine 10 is set in the work area 221 for specific control. 221 is cleared to “0” and the initial setting is executed. As a result, the area indicating whether or not the winning/winning lottery mode is the high-probability mode is cleared to "0". The mode is a low probability mode. In addition, the game times are not being executed, the opening/closing execution mode is not being executed, and the general-purpose display unit 38a is not being variably displayed, and the general electric accessory 34a is in the closed state. It becomes a situation. Further, since the hold storage area 65a and the universal electric power reserve area 65c provided in the work area 221 for specific control are also cleared to "0", the reserved information for the special figure display section 37a is deleted and the general figure display section is deleted. The hold information for 38a is deleted. In the RAM clearing process, the stack area 222 for specific control is cleared to "0" and the initial setting is executed. In the RAM clearing process, various registers of the main CPU 63 are cleared to "0" and then the initial setting is executed. In this initial setting, the same processing as the internal function register setting processing of step S7902 (step S7902) is executed.

On the other hand, in the RAM clear processing, the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to "0". This makes it possible to prevent the work area 223 for non-specific control and the stack area 224 for non-specific control from being cleared to "0" by the clearing operation by the manager of the game hall.

Then, it is determined whether or not the setting key insertion portion 68a is turned on by using the setting key (step S7916), and the front door frame 14 is opened with respect to the inner frame 13 and the outer frame 11 is opened. Then, it is determined whether or not the gaming machine body 12 is in the open state (step S7917). The front door opening sensor 95 is used to detect whether or not the front door frame 14 is opened with respect to the inner frame 13 as in the thirtieth embodiment, and the gaming machine main body 12 is detected with respect to the outer frame 11. The main body open sensor 96 is used to detect whether or not it is in the open state, as in the thirtieth embodiment. The setting key insertion portion 68a is turned on by using the setting key (step S7916: YES), the front door frame 14 is open to the inner frame 13, and the gaming machine main body is opened to the outer frame 11. If 12 is in the open state (step S7917: YES), the set value update processing is executed (step S7918).

FIG. 116 is a flowchart showing the setting value update processing. The processing of steps S8101 to S8107 in the setting value update processing is executed using the specific control program and specific control data in the main CPU 63.

First, "1" is set to the setting update display flag provided in the work area 221 for specific control (step S8101). The setting update display flag is a flag for the main CPU 63 to specify that the setting value of the pachinko machine 10 is being updated. When the setting update display flag is set to "1", the corresponding display control is performed to the first to fourth notification display devices 201 to 204 in the second timer interrupt process (FIG. 123) described later. Be seen. Thereby, on the first to fourth display devices 201 to 204, a display indicating that the setting value of the pachinko machine 10 is being updated and a display indicating the current setting value of the pachinko machine 10 are displayed. Be seen.

Then, it is determined whether or not the value of the set value counter provided in the work area 221 for specific control is 1 or more corresponding to "setting 1" and 6 or less corresponding to "setting 6" (step S8102). When the value of the set value counter is “0” or is 7 or more, a negative determination is made in step S8102 and “1” is set in the set value counter (step S8103). As a result, the set value of the pachinko machine 10 becomes "setting 1".

If an affirmative decision is made in step S8102, or if the processing of step S8103 is executed, it is decided whether or not the setting key inserting section 68a has been turned off using the setting key (step S8104). In this case, it may be configured to determine whether the setting key inserting section 68a is switched from the ON state to the OFF state, or may be configured to determine whether the setting key inserting section 68a is in the OFF state.

When the setting key insertion portion 68a is not turned off (step S8104: NO), the set value counter in the work area 221 for specific control is provided on condition that the reset button 68c is pressed (step S8105: YES). Is incremented by 1 (step S8106). As a result, each time the reset button 68c is pressed once, the setting value is updated by one step. If the reset button 68c is not pressed (step S8105: NO) or if the value of the set value counter is incremented by 1, the process returns to step S8102. If it is determined that the value is 7 or more, "1" is set in the set value counter in step S8103. As a result, when the reset button 68c is pressed once in the situation of "setting 6", the process returns to "setting 1".

When the setting key insertion unit 68a is turned off (step S8104: YES), the setting update display flag in the specific control work area 221 is cleared to "0" (step S8107). Thereby, on the first to fourth display devices 201 to 204, a display indicating that the setting value of the pachinko machine 10 is being updated and a display indicating the current setting value of the pachinko machine 10 are displayed. The state of being exposed is released. In this case, the display indicating the management result of the game history is started on the first to fourth notification display devices 201 to 204.

As described above, in the present embodiment, when the power of the pachinko machine 10 is turned on while pressing the reset button 68c, resetting is performed in a situation where the supply of operating power to the main CPU 63 is started and the main processing is started. The button 68c is pressed, and the RAM clearing process (step S7915) is executed regardless of whether the setting key insertion unit 68a is turned ON. As a result, the operation content of powering on the pachinko machine 10 while pressing the reset button 68c is uniquely linked to the execution of the RAM clear processing (step S7915), and the RAM clear processing (step S7915) is executed. The operation content to be generated can be easily understood by the game hall manager.

Even if the RAM clearing process (step S7915) is executed, the set value counter in the specific control work area 221 is not cleared to "0" and the set value counter information is not changed. This makes it possible to prevent the set value from being changed even if the RAM clear process (step S7915) is executed.

RAM clear processing based on not only turning on the power of the pachinko machine 10 while pressing the reset button 68c, but also turning on the power of the pachinko machine 10 while turning on the setting key insertion part 68a with the setting key. Not only (step S7915), but also the set value updating process (step S7918) is executed. In addition, as described above, the setting confirmation process (step S7914) is performed based on the power-on operation of the pachinko machine 10 while the setting key insertion portion 68a is turned on by the setting key without pressing the reset button 68c. To be executed. As a result, it becomes possible to make the ON operation for the setting key insertion unit 68a common as the operation for executing the process related to the set value. Therefore, it becomes possible for the manager of the game hall to easily understand the operation content for generating the processing related to the set value.

Further, when the power of the pachinko machine 10 is turned on while the setting key insertion portion 68a is turned on by the setting key, and the pressing operation of the reset button 68c is not added, the setting confirmation processing is executed and reset. When the pressing operation of the button 68c is added, the set value updating process is executed. As a result, it becomes possible to make the setting confirmation process and the setting value update process different from each other depending on whether or not the reset button 68c is pressed. Therefore, it becomes possible for the manager of the game hall to easily understand the operation content for executing the desired processing among the setting confirmation processing and the setting value updating processing. Further, by increasing the number of operations for executing the setting value updating process more than the setting confirming process, it becomes possible to make it particularly difficult to illegally perform the setting value updating process.

Returning to the description of the main process (FIG. 114 ), when the process of step S7911 is executed, when the negative determination is made in step S7912 or step S7913, when the process of step S7914 is executed, negative in step S7916 or step S7917. When the determination is made or when the processing of step S7918 is executed, the startup processing flag in the work area 221 for specific control is cleared to "0" (step S7919). By clearing the start-up processing flag to "0", the state in which the various processes set in the first timer interrupt processing are not executed is canceled even if the first timer interrupt processing is started. In step S7919, the power failure flag in the specific control work area 221 is also cleared to "0".

After that, the return command is transmitted to the voice emission control device 81 (step S7920). The return command indicates information indicating the number of holding information for the special figure display unit 37a, information indicating the current win/fail lottery mode, information indicating the current support mode, and whether or not the opening/closing execution mode is being executed. The information and the information indicating whether or not the game game is being executed are included. These pieces of information are set based on the information stored in the work area 221 for specific control. By receiving the return command, the voice emission control device 81 corresponds the display content of the symbol display device 41, the light emission content of the display light emitting unit 53 and the sound output content of the speaker unit 54 to various information set in the return command. What to do

Here, when confirming the set value of the pachinko machine 10, it is necessary to turn on the power of the pachinko machine 10 while turning on the setting key insertion portion 68a with the setting key. Then, for example, when it is necessary to confirm the set value during the execution of the game time, the power of the pachinko machine 10 is turned off during the execution of the game time, and then the setting key insertion portion 68a is operated by the setting key. The power ON operation of the pachinko machine 10 is performed while the ON operation is performed. In this case, backup power is not supplied to the RAM provided in the sound emission control device 81, so at the stage when the power of the pachinko machine 10 is turned off, the effect for game play in the RAM of the sound emission control device 81 is generated. The information for controlling is erased. On the other hand, the backup power is supplied to the main RAM 65 and the clearing process of the main RAM 65 is not executed when confirming the set value, so the power of the pachinko machine 10 is turned off during the game play. After that, when the power of the pachinko machine 10 is turned on while the setting key insertion section 68a is turned on by the setting key, the variation display of the pattern is displayed on the special figure display section 37a after the setting confirmation process is executed. Will be restarted. Then, although the special figure display unit 37a displays the variable display of the pattern, a situation occurs in which the variable display of the pattern is not displayed on the symbol display device 41.

On the other hand, after the setting confirmation process is completed, a return command is transmitted to the voice emission control device 81, and the return command includes information indicating whether or not the game game is being executed. When the sound emission control device 81 receives the return command, it causes the symbol display device 41 to start the variable display of symbols. As a result, it is possible to prevent a situation in which the variable display of the symbols is not performed on the symbol display device 41 even though the variable display of the symbols is performed on the special figure display unit 37a. .. The variable display of the symbols is performed at a relatively high speed so that the symbols in the variable display become indistinguishable or difficult for the player to identify. Further, the return command does not include the result of the hit determination processing and the result of the distribution determination processing of the game time to be restarted, and does not include the information indicating the end timing of the game time to be restarted. Therefore, when the voice emission control device 81 starts the variable display of the symbols on the symbol display device 41 based on the return command, if the game time to be restarted corresponds to the deviation result, the next game time is started. When the command shown or a command to start the demo display is received by the symbol display device 41, the variable display of the symbol based on the return command is ended and the display corresponding to the newly received command is started to be restarted. If the game number corresponds to the jackpot result, when the opening command indicating the start of the opening/closing execution mode is received, the variable display of the symbols based on the return command is ended and the opening effect is started.

When the return command includes information indicating that the opening/closing execution mode is being executed, the sound emission control device 81 starts the display effect indicating that the opening/closing execution mode is in the opening/closing execution mode on the symbol display device 41. To be done. This enables the player to recognize that the open/close execution mode is being executed.

After that, the process proceeds to the residual process of steps S7921 to S7924. That is, the main CPU 63 is configured to periodically execute the first timer interrupt process (FIG. 117) and the second timer interrupt process (FIG. 123), but between the one timer interrupt process and the next timer interrupt process. There will be some residual time. This remaining time will vary depending on the processing completion time of each timer interrupt processing, but the remaining processing of steps S7921 to S7924 is repeatedly executed by utilizing this irregular time. In this respect, it can be said that the residual process of steps S7921 to S7924 is an irregular process that is irregularly executed. In steps S7921 to S7924, the same processing as steps S113 to S116 of the main processing (FIG. 9) in the first embodiment is executed.

Next, the first timer interrupt process executed by the main CPU 63 will be described with reference to the flowchart of FIG. 117. It should be noted that the first timer interrupt process is periodically activated at the 4 ms cycle, which is the first interrupt cycle, as already described. Further, the program corresponding to the first timer interrupt processing is set to the program for specific control.

First, it is determined whether or not "1" is set in the startup processing flag in the work area 221 for specific control (step S8201). As described above, the start-up processing flag is set to "1" in step S7903 of the main processing (FIG. 114). When the start-up processing flag is set to "1" (step S8201: YES), the first timer interrupt processing is ended without executing the various processing of steps S8202 to S8221. Thus, when the supply of operating power to the pachinko machine 10 is started and the main process (FIG. 114) is started, the execution of the first timer interrupt process and the second timer interrupt process is permitted early. Even if there is, various processes for controlling the progress of the game in the first timer interrupt process are performed until the process at the start of the supply of the operating power is finished and the execution of the process for controlling the progress of the game is permitted. It is possible to prevent it from being executed.

As described above, the startup processing flag is cleared to "0" in step S7919 when the processing at the start of supplying the operating power is completed in the main processing (FIG. 114). In the first timer interrupt process, when “1” is not set in the startup process flag (step S8201: NO), the processes of step S8202 and thereafter are executed.

In steps S8202 to S8219 and step S8221, the same processes as steps S3701 to S3719 of the timer interrupt process (FIG. 69) in the fifteenth embodiment are executed. These processes are executed by the main CPU 63 using a specific control program and specific control data. In this case, if it is determined that the power failure flag is not set to "1" in the main process (FIG. 114) as described above (step S7906: NO) or it is determined that the checksums do not match (step S7906). (S7909: NO), "1" is set to the game stop flag in the work area 221 for specific control (step S7910). When the game stop flag is set to "1", the first timer interrupt process executes the processes of steps S8201 to S8206, but makes a positive determination in step S8207 to execute the processes of steps S8208 to S8221. Do not run. As a result, if the power failure flag is not set to "1" because the power failure process was not properly performed at the previous power shutdown, the game progress is stopped and the specific control is performed. If at least one of the work area 221 and the stack area 222 for specific control does not match the checksums due to the change in the storage state of information since the last power-off, the progress of the game is stopped. It will be in a state of being. For example, since the process of step S8212 is not executed, the launch of the game ball is prohibited. In addition, since the process of step S8214 is not executed, execution of the game times and the opening/closing execution mode is prohibited. Further, since the process of step S8218 is not executed, the payout of gaming balls is prohibited.

On the other hand, even in the situation where the progress of the game is stopped in this way, the power failure monitoring is executed in step S8202, and the winning random number counter C1, the jackpot type counter C2, and the reach random number counter C3 in steps S8203 and S8204. Then, the random number initial value counter CINI is updated, and further fraud detection is executed in step S8206.

In the first timer interrupt processing, the setting monitoring processing is executed in step S8220. FIG. 118 is a flowchart showing the setting monitoring process. The processes of steps S8301 to S8303 in the setting monitoring process are executed using the specific control program and the specific control data in the main CPU 63.

By checking the value of the set value counter in the work area 221 for specific control, it is determined whether or not the set value of the pachinko machine 10 is normal (step S8301). Specifically, when the set value set in the set value counter is any of "setting 1" to "setting 6", it is determined to be normal, and when it is "0" or 7 or more, there is an abnormality. Judge that there is.

When the set value is abnormal (step S8301: NO), "1" is set to the game stop flag in the specific control work area 221 as in step S7910 in the main process (FIG. 114) (step S8302). When the game stop flag is set to "1", an affirmative determination is made in step S8207 of the first timer interrupt processing (FIG. 117), and the processing in steps S8208 to S8221 is not executed. As a result, when it is specified that the set value is abnormal, the progress of the game is stopped. On the other hand, even if the game stop flag is set to "1", the processes of steps S8202 to S8206 in the first timer interrupt process (FIG. 117) are executed, so that the progress of the game is stopped. Even in a situation where the power failure is monitored, the winning random number counter C1, the big hit type counter C2, the reach random number counter C3, and the random number initial value counter CINI are updated, and further fraud detection is executed.

After that, an abnormal command indicating that the set value is abnormal is transmitted to the voice emission control device 81 (step S8303). Upon receipt of the abnormal command, the voice emission control device 81 causes the display light emitting unit 53 to emit light in a manner corresponding to the abnormal set value, and causes the speaker unit 54 to output the voice "Please change the setting." .. Moreover, the character image "Please change the setting." is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are ended when the supply of operating power to the pachinko machine 10 is stopped. However, even if the supply of the operating power to the pachinko machine 10 is temporarily stopped, the supply of the operating power to the pachinko machine 10 is restarted until the setting value updating process (step S7918) of the main process (FIG. 114) is executed. It may be configured such that the notification is continued in the case of being notified.

The manager of the game hall, who has confirmed the above notification in the situation where the progress of the game is stopped, temporarily stops the supply of operating power to the pachinko machine 10 and then resumes the supply of operating power to the pachinko machine 10. In this case, an operation for executing the set value updating process (step S7918) is performed. This makes it possible to newly set the set value in the set value updating process (step S7918) when the set value abnormality occurs.

Here, the monitoring process for determining whether or not the set value is abnormal is executed by the first timer interrupt process (FIG. 117) that is regularly activated. Thereby, it becomes possible to monitor whether or not the set value is abnormal even in a situation where a game is being played. Therefore, it is possible to prevent the game from being continued even if the set value is abnormal. Further, the monitoring of whether or not the set value is abnormal is executed every time a monitoring trigger occurs. As a result, it is possible to increase the frequency of monitoring whether the set value is abnormal.

In the main process (FIG. 114), the process for monitoring whether or not the set value is normal is not set. When the process for monitoring whether or not the set value is normal is set in the process at the start of supplying the operating power in the main process (FIG. 114), the power failure flag and the checksum are set at the start of supplying the operating power. It becomes necessary to monitor whether or not the set value is normal, in addition to the above-mentioned monitoring, which increases the monitoring load. Further, when it is determined that the set value is abnormal at the start of the supply of the operating power, the RAM clear process (step S7915) and the set value update process (step S7918) are attempted to be executed. Becomes complicated. On the other hand, since the process for monitoring whether the set value is normal is not set in the main process (FIG. 114), the processing configuration of the process at the start of supplying the operating power is preferable. It becomes possible. Even if the process for monitoring whether or not the set value is normal is not set in the process at the start of supplying the operating power as described above, the first timer interrupt process (FIG. 117) is performed as described above. Since the setting monitoring process (step S8220) is executed by the above, if the set value is abnormal, it can be dealt with.

In the configuration in which the first timer interrupt process is executed as described above, the second timer interrupt process (FIG. 123) is provided separately from the first timer interrupt process (FIG. 117) as the timer interrupt process in the present embodiment as already described. While existing, the second timer interrupt process is activated by interrupting the first timer interrupt process even during execution of the first timer interrupt process. In this case, although not shown in the first timer interrupt process, the timer interrupt process is prohibited and the timer interrupt process is permitted before and after each process of steps S8201 to S8221. For example, the timer interrupt process is prohibited before executing the lottery random number updating process (step S8203), and the timer interrupt process is permitted after executing the lottery random number updating process (step S8203). As a result, it is possible to prevent the second timer interrupt process from being interrupted and activated during the execution of the lottery random number updating process. Further, the timer interrupt process is prohibited before the special figure special power control process (step S8214) is executed, and the timer interrupt process is permitted after the special figure special power control process (step S8214) is executed. As a result, it is possible to prevent the second timer interrupt process from being interrupted and activated during the execution of the special figure special power control process.

Next, a configuration for display control of various display units by the main CPU 63 will be described. FIG. 119 is a block diagram for explaining a configuration for controlling display of various display units by the main CPU 63.

Targets for which display control is performed by the main CPU 63 are special figure display section 37a, special figure reservation display section 37b, general figure display section 38a, general figure reservation display section 38b, and first to fourth notification display devices 201 to 201. 204 exists. Each of these is provided as a segment display unit in which a plurality of display segments by LEDs are arranged. These segment display parts are in a light emitting state when data corresponding to a light emitting state (for example, one of binary data “1” data) is set, and data corresponding to a light extinguishing state (for example, binary data The other one, "0" data), is set to turn off the light.

The main control board 61 is provided with a first display circuit 261 corresponding to the special figure display portion 37a, and a second display circuit 262 corresponding to the special figure reservation display portion 37b. A third display circuit 263 is provided corresponding to the display portion 38a, a fourth display circuit 264 is provided corresponding to the universal figure reservation display portion 38b, and the first to fourth notification display devices 201 to 201 are provided. A fifth display circuit 265 is provided corresponding to 204. In the eleventh embodiment, the first to fourth display ICs 205 to 208 are provided on the main control board 61 in a one-to-one correspondence with the first to fourth notification display devices 201 to 204. However, these first to fourth display ICs 205 to 208 are not provided in the present embodiment.

The first display circuit 261 provides data corresponding to the supplied display data to each of the plurality of display segments of the special figure display portion 37a. As a result, each display segment of the special figure display portion 37a is turned on or off in a manner corresponding to the display data provided to the first display circuit 261. In this case, the first display circuit 261 can store and hold the provided display data for a predetermined period (for example, 16 milliseconds), but when the predetermined period elapses, the display data is gradually changed to "0". It will approach the state of. Therefore, the display segment of the special figure display portion 37a which is in the light emitting state due to the display data provided to the first display circuit 261 has passed the predetermined period without new display data being provided to the first display circuit 261. By doing so, the light is gradually turned off. Further, due to such a configuration, not only when the display content of the special figure display unit 37a is changed but also when the display content of the special figure display unit 37a is not changed, the output processing of the previous display data is performed. The same display data as the times is supplied to the first display circuit 261.

The number of display segments provided in the special figure display portion 37a is eight. Therefore, 8-bit data is provided to the first display circuit 261 as display data for controlling the display of the special figure display portion 37a.

The second display circuit 262 provides data corresponding to the supplied display data to each of the plurality of display segments of the special figure reservation display portion 37b. As a result, each display segment of the special figure reservation display portion 37b is turned on or off in a manner corresponding to the display data provided to the second display circuit 262. In this case, the second display circuit 262 can store and hold the provided display data for a predetermined period (for example, 16 milliseconds), but when the predetermined period elapses, the display data is gradually changed to "0". It will approach the state of. Therefore, the display segment of the special figure reservation display portion 37b which is in a light emitting state by the display data provided to the second display circuit 262 is not provided with new display data for a predetermined period. The light is gradually turned off as time passes. Further, due to such a configuration, not only when the display content of the special figure reservation display section 37b is changed but also when the display content of the special figure reservation display section 37b is not changed, the previous display data The same display data as the output processing time is supplied to the second display circuit 262.

The number of display segments provided in the special figure reservation display portion 37b is four. Therefore, 4-bit data is provided to the second display circuit 262 as display data for controlling the display of the special figure reservation display portion 37b. However, since the display data is provided in 8-bit units, even when the display data is provided to the second display circuit 262, 8-bit data is provided. It is used as display data for controlling the display of 37b.

The third display circuit 263 provides data corresponding to the supplied display data to each of the plurality of display segments of the normal figure display unit 38a. As a result, each display segment of the general-purpose display section 38a is turned on or off in a mode corresponding to the display data provided to the third display circuit 263. In this case, the third display circuit 263 can store and hold the provided display data for a predetermined period (for example, 16 milliseconds), but after the predetermined period elapses, the display data is gradually changed to "0". It will approach the state of. Therefore, the display segment of the general-purpose display section 38a which is in a light emitting state according to the display data provided to the third display circuit 263 has passed the predetermined period without being provided with new display data to the third display circuit 263. By doing so, the light is gradually turned off. Further, due to such a configuration, not only when the display content of the public figure display unit 38a is changed but also when the display content of the general figure display unit 38a is not changed, the output processing of the previous display data is performed. The same display data as the times is supplied to the third display circuit 263.

The number of display segments provided on the general-drawing display section 38a is eight. Therefore, 8-bit data is provided to the third display circuit 263 as display data for controlling the display of the universal figure display unit 38a.

The fourth display circuit 264 provides data corresponding to the supplied display data to each of the plurality of display segments of the universal figure reservation display section 38b. As a result, each display segment of the universal figure reservation display section 38b is turned on or off in a manner corresponding to the display data provided to the fourth display circuit 264. In this case, the fourth display circuit 264 can store and hold the provided display data for a predetermined period (for example, 16 milliseconds), but when the predetermined period elapses, the display data gradually becomes all “0”. It will approach the state of. Therefore, the display segment of the universal figure reservation display unit 38b which is in the light emitting state by the display data provided to the fourth display circuit 264 is not provided with new display data for the predetermined period, The light is gradually turned off as time passes. Further, due to such a configuration, not only when the display content of the universal figure hold display section 38b is changed but also when the display content of the universal figure hold display section 38b is not changed, the previous display data The same display data as the output processing time is supplied to the fourth display circuit 264.

The number of display segments provided on the universal figure reservation display section 38b is four. Therefore, 4-bit data is provided to the fourth display circuit 264 as display data for controlling the display of the universal figure reservation display unit 38b. However, since the display data is provided in units of 8 bits, even when the display data is provided to the fourth display circuit 264, the 8-bit data is provided. 38b is used as display data for display control.

The fifth display circuit 265 provides data corresponding to the supplied display data to each of the plurality of display segments provided in each of the first to fourth notification display devices 201 to 204. As a result, the display segments of the first to fourth notification display devices 201 to 204 are turned on or off in a manner corresponding to the display data provided to the fifth display circuit 265. In this case, the fifth display circuit 265 can store and hold the provided display data for a predetermined period (for example, 16 milliseconds), but after the predetermined period elapses, the display data gradually becomes all "0". It will approach the state of. Therefore, new display data is provided to the fifth display circuit 265 in the display segments of the first to fourth notification display devices 201 to 204 which are in the light emitting state according to the display data provided to the fifth display circuit 265. The light gradually goes out after a predetermined period of time elapses. Further, due to such a configuration, not only when the display contents of the first to fourth notification display devices 201 to 204 are changed, but also the display contents of the first to fourth notification display devices 201 to 204 are changed. Even when the display data is not output, the same display data as the previous display data output processing time is supplied to the fifth display circuit 265.

Seven display segments are provided on each of the first to fourth notification display devices 201 to 204. On the other hand, the display data is provided in 8-bit units. When the display data of the first to fourth notification display devices 201 to 204 is provided to the fifth display circuit 265, 7-bit display data corresponding to the first notification display device 201 is provided as 8-bit unit data. Then, 7-bit display data corresponding to the second notification display device 202 is provided as 8-bit unit data, and then 7-bit display data corresponding to the third notification display device 203 is provided in 8-bit units. And finally, 7-bit display data corresponding to the fourth annunciation display device 204 is provided as 8-bit unit data.

In the configuration in which the first to fifth display circuits 261 to 265 are provided as described above, the main CPU 63 supplies the display data to the display IC 266. That is, the display ICs 266 are not provided on the first to fifth display circuits 261 to 265 in a one-to-one manner, but one display IC 266 is provided so as to be common to all of the first to fifth display circuits 261 to 265. The display IC 266 is provided. When the main CPU 63 supplies the display data to the display IC 266, the main CPU 63 also supplies to the display IC 266 classification data indicating which of the first to fifth display circuits 261 to 265 the display data corresponds to.

For details of the electrical connection between the main CPU 63 and the display IC 266, the main CPU 63 and the display IC 266 include the type data signal line LN1, the type clock signal line LN2, the display data signal line LN3, and the display clock signal. It is electrically connected using the line LN4. All of these signal lines LN1 to LN4 are signal lines for transmitting signals from the main CPU 63 to the display IC 266 by one-way communication.

The type data is transmitted from the main CPU 63 to the display IC 266 by serial communication using the type data signal line LN1. In this case, each 1-bit delimiter of the type data by serial communication is indicated by the type clock signal transmitted from the main CPU 63 to the display IC 266 using the type clock signal line LN2. The type data is data indicating which of the first to fifth display circuits 261 to 265 the display data to be transmitted corresponds to. The type data is transmitted as 5-bit data including the first bit to the fifth bit. When the display data corresponds to the first display circuit 261, the first bit becomes HI level and the other bits become LOW level. When the display data corresponds to the second display circuit 262, the second bit becomes HI level and the other bits become LOW level. When the display data corresponds to the third display circuit 263, the third bit becomes HI level and the other bits become LOW level. When the display data corresponds to the fourth display circuit 264, the fourth bit becomes HI level and the other bits become LOW level. When the display data corresponds to the fifth display circuit 265, the fifth bit becomes HI level and the other bits become LOW level.

Display data is transmitted from the main CPU 63 to the display IC 266 by serial communication using the display data signal line LN3. In this case, each 1-bit segment of the display data by serial communication is indicated by the display clock signal transmitted from the main CPU 63 to the display IC 266 using the display clock signal line LN4. The display data is transmitted in 8-bit units of the first to eighth bits.

The main CPU 63 transmits the display data corresponding to each of the first to fifth display circuits 261 to 265 to the display IC 266 by the second timer interrupt process (FIG. 123) described later. In this case, the display data is transmitted to one of the first to fifth display circuits 261 to 265 and the nth display circuit→the n+1th display is performed once in the second timer interrupt processing. Each time a new processing time of the second timer interrupt processing occurs, the display circuits 261 to 265 to which the display data are transmitted are changed one by one according to the order of the circuits. In addition, in the second timer interrupt processing in the processing cycle subsequent to the processing cycle in which the display data corresponding to the fifth display circuit 265, which is the final cycle in the order, is transmitted, the first display circuit 261 in the first cycle in the above order. The display data corresponding to is transmitted. It should be noted that although only one piece of display data in 8-bit units is transmitted in the processing time of the second timer interrupt processing for transmitting display data to any of the first to fourth display circuits 261 to 264, the fifth display circuit 265 In the processing time of the second timer interrupt processing for transmitting the display data to the display device, four pieces of display data in 8-bit units are transmitted corresponding to the numbers of the first to fourth notification display devices 201 to 204.

In the configuration in which the main CPU 63 transmits the display data as described above, the storage area 221 for the specific control and the work area 223 for the non-specific control are various storage areas referred to by the main CPU 63 for transmitting the display data. Is set. FIG. 120(a) is an explanatory diagram for explaining various buffers 271 to 275 provided in the work area 221 for specific control, and FIG. 120(b) is provided in the work area 223 for non-specific control. It is an explanatory view for explaining various storage areas 234 and 276.

As shown in FIG. 120A, in the work area 221 for specific control, the first display data buffer 271, the second display data buffer 272, the third display data buffer 273, the fourth display data buffer 274, A fifth display data buffer 275 is provided.

Display data to be supplied to the first display circuit 261 is stored in the first display data buffer 271. Since the first display circuit 261 is provided corresponding to the special figure display unit 37a as already described, the first display data buffer 271 contains the display data for causing the special figure display unit 37a to perform a predetermined display. Will be stored. In this case, the display data is stored in the first display data buffer 271 in the display control process (step S8216) in consideration of the contents of the special figure special power control process (step S8214) in the first timer interrupt process (FIG. 117). .. Further, when the processing time of the second timer interrupt processing (FIG. 123) for transmitting the display data to the first display circuit 261 is reached, only when the display data stored in the first display data buffer 271 is changed. Instead, even if the display data is not changed, the display data stored in the first display data buffer 271 is transmitted to the display IC 266.

The display data to be supplied to the second display circuit 262 is stored in the second display data buffer 272. Since the second display circuit 262 is provided corresponding to the special figure reservation display section 37b as described above, the second display data buffer 272 is a display for causing the special figure reservation display section 37b to perform a predetermined display. The data will be stored. In this case, the display data is stored in the second display data buffer 272 in the display control process (step S8216) based on the contents of the special figure special power control process (step S8214) in the first timer interrupt process (FIG. 117). .. Further, when the processing time of the second timer interrupt processing (FIG. 123) for transmitting the display data to the second display circuit 262 is reached, only when the display data stored in the second display data buffer 272 is changed. Instead, even if the display data is not changed, the display data stored in the second display data buffer 272 is transmitted to the display IC 266.

The third display data buffer 273 stores the display data to be supplied to the third display circuit 263. As described above, the third display circuit 263 is provided in association with the public figure display unit 38a, so that the third display data buffer 273 has display data for causing the public figure display unit 38a to perform a predetermined display. Will be stored. In this case, the display data is stored in the third display data buffer 273 by the display control process (step S8216) in consideration of the contents of the universal figure universal power control process (step S8215) in the first timer interrupt process (FIG. 117). Be seen. Further, when the processing time of the second timer interrupt processing (FIG. 123) for transmitting the display data to the third display circuit 263 is reached, only when the display data stored in the third display data buffer 273 is changed. Instead, even if the display data is not changed, the display data stored in the third display data buffer 273 is transmitted to the display IC 266.

The display data to be supplied to the fourth display circuit 264 is stored in the fourth display data buffer 274. As described above, the fourth display circuit 264 is provided corresponding to the universal figure hold display section 38b, and therefore, the fourth display data buffer 274 displays a display for causing the universal figure hold display section 38b to perform a predetermined display. The data will be stored. In this case, the display data is stored in the fourth display data buffer 274 by the display control process (step S8216) in consideration of the contents of the universal figure/general electric power control process (step S8215) in the first timer interrupt process (FIG. 117). Be seen. Further, when the processing time of the second timer interrupt processing (FIG. 123) for transmitting the display data to the fourth display circuit 264 is reached, only when the display data stored in the fourth display data buffer 274 is changed. Instead, the display data stored in the fourth display data buffer 274 is transmitted to the display IC 266 even when the display data is not changed.

The fifth display data buffer 275 stores the display data to be supplied to the fifth display circuit 265. Since the fifth display circuit 265 is provided corresponding to the first to fourth notification display devices 201 to 204 as already described, the fifth display data buffer 275 has the first to fourth notification display devices 201. The display data for causing the display units 204 to 204 to perform the predetermined display is stored. When the processing time of the second timer interrupt processing for transmitting the display data to the fifth display circuit 265 is reached, not only when the display data stored in the fifth display data buffer 275 is changed, but also the display data concerned. Even if is not changed, the display data stored in the fifth display data buffer 275 is transmitted to the display IC 266.

Here, the display corresponding to the management result of the game history is performed on the first to fourth notification display devices 201 to 204, and the setting confirmation process (FIG. 115) or the setting value update process (FIG. 116) is executed. If it does, a display corresponding to the current set value is displayed. In this case, since the fifth display data buffer 275 is provided in the work area 221 for specific control, the process of storing the display data in the fifth display data buffer 275 is performed as the process corresponding to the specific control. On the other hand, the process for deriving the management result of the game history is performed as a process corresponding to the non-specific control, and the 61st parameter to the 68th parameter, which are the management result of the game history, are the first to fourth notification display devices. Items 201 to 204 are sequentially displayed.

Therefore, as shown in FIG. 120B, not only the calculation result storage area 234 for storing the 61st parameter to the 68th parameter in the work area 223 for non-specific control, but also the 61st parameter to the 68th parameter. A display target setting area 276 for storing parameters to be displayed on the first to fourth notification display devices 201 to 204 is provided. Even in the present embodiment, as in the case of the fifteenth embodiment, the period in which the calculation result of one parameter is continuously displayed is 10 seconds. Every time a second elapses, the calculation result of the parameter to be displayed is read from the calculation result storage area 234 according to the predetermined display order, and the calculation result of the read parameter is stored in the display target setting area 276. R. When the game history management result is displayed on the first to fourth notification display devices 201 to 204, the second timer interrupt process (FIG. 123) corresponding to the specific control is performed. The display data stored in the display target setting area 276 is read, and the read display data is stored in the fifth display data buffer 275.

On the other hand, when the setting confirmation process (FIG. 115) is being executed, the first to fourth notification displays are displayed in the second timer interrupt process (FIG. 123) which is a process corresponding to the specific control. The display data for allowing the devices 201 to 204 to display the current setting value of the pachinko machine 10 and the display indicating the current setting value of the pachinko machine 10 are the fifth display data. It is stored in the display data buffer 275. Further, when the setting value updating process (FIG. 116) is being executed, the second timer interrupt process (FIG. 123), which is a process corresponding to the specific control, displays the first to fourth notification displays. The display data for displaying that the setting values of the pachinko machine 10 are being updated in the devices 201 to 204 and the display showing the current setting values of the pachinko machine 10 are the fifth display data. It is stored in the buffer 275.

In the configuration in which the first to fifth display data buffers 271 to 275 are provided as described above, the main CPU 63 makes the display data corresponding to each processing time of the second timer interrupt processing (FIG. 123). The display data is read from the buffers 271-275, the read display data is transmitted to the display IC 266, and type data indicating which of the first to fifth display circuits 261 to 265 the display data corresponds to is displayed. It is transmitted to the display IC 266. FIG. 121 is an explanatory diagram for explaining the electrical configuration of the display IC 266.

As shown in FIG. 121, the display IC 266 includes a type data buffer 281, a selection signal output unit 282, a display data buffer 283, and a display data output unit 284. The display data buffer 283 stores the display data received from the main CPU 63. The display data output unit 284 transmits the display data stored in the display data buffer 283 to the first to fifth display circuits 261 to 265. The type data buffer 281 stores the type data received from the main CPU 63. The selection signal output unit 282 is a selection signal for designating the display circuits 261 to 265 corresponding to the type data stored in the type data buffer 281 among the first to fifth display circuits 261 to 265 as the receiving destination of the display data. Is output.

In detail, as shown in FIG. 119, the display IC 266 and the first display circuit 261 are electrically connected using the display signal group 291. The display signal group 291 is provided so as to be able to transmit 8-bit display data at a time, and the 8-bit unit display data is transmitted from the display IC 266 by parallel communication. A branch signal group 292 is provided by branching from the display signal group 291, and the branch signal group 292 includes the second display circuit 262, the third display circuit 263, the fourth display circuit 264, and the fifth display circuit 265. Are electrically connected to each of the. The branch signal group 292 is provided so as to be able to transmit 8-bit display data at a time, like the display signal group 291, and the 8-bit unit display data is transmitted from the display IC 266 by parallel communication. It

Since the display signal group 291 and the branch signal group 292 are provided as described above, when the display data stored in the display data buffer 283 is transmitted by the display data output unit 284, the display data is Is supplied to all the fifth display circuits 261 to 265. In this case, the first to fifth selection signal lines 301 to 305 are provided to receive the supplied display data and specify the display circuits 261 to 265 to be used.

The first selection signal line 301 is provided so as to electrically connect the display IC 266 and the first display circuit 261. When the type data buffer 281 stores the type data corresponding to the first display circuit 261, in order to cause the first display circuit 261 to receive and use the display data supplied from the display data output unit 284. The selection signal output unit 282 of the display IC 266 transmits the first selection signal to the first display circuit 261 through the first selection signal line 301. As a result, the display data supplied to all of the first to fifth display circuits 261 to 265 through the display signal group 291 and the branch signal group 292 is received and used only in the first display circuit 261.

The second selection signal line 302 is provided so as to electrically connect the display IC 266 and the second display circuit 262. When the type data buffer 281 stores the type data corresponding to the second display circuit 262, in order to cause the second display circuit 262 to receive and use the display data supplied from the display data output unit 284. The selection signal output unit 282 of the display IC 266 transmits the second selection signal to the second display circuit 262 through the second selection signal line 302. As a result, the display data supplied to all of the first to fifth display circuits 261 to 265 through the display signal group 291 and the branch signal group 292 is received and used only in the second display circuit 262.

The third selection signal line 303 is provided so as to electrically connect the display IC 266 and the third display circuit 263. When the type data corresponding to the third display circuit 263 is stored in the type data buffer 281, in order to make the third display circuit 263 receive and use the display data supplied from the display data output unit 284. The selection signal output unit 282 of the display IC 266 transmits the third selection signal to the third display circuit 263 through the third selection signal line 303. As a result, the display data supplied to all the first to fifth display circuits 261 to 265 through the display signal group 291 and the branch signal group 292 is received and used only in the third display circuit 263.

The fourth selection signal line 304 is provided so as to electrically connect the display IC 266 and the fourth display circuit 264. When the type data buffer 281 stores the type data corresponding to the fourth display circuit 264, in order to cause the fourth display circuit 264 to receive and use the display data supplied from the display data output unit 284. The selection signal output unit 282 of the display IC 266 transmits the fourth selection signal to the fourth display circuit 264 through the fourth selection signal line 304. As a result, the display data supplied to all of the first to fifth display circuits 261 to 265 through the display signal group 291 and the branch signal group 292 is received and used only in the fourth display circuit 264.

The fifth selection signal line 305 is provided so as to electrically connect the display IC 266 and the fifth display circuit 265. When the type data buffer 281 stores the type data corresponding to the fifth display circuit 265, in order to cause the fifth display circuit 265 to receive and use the display data supplied from the display data output unit 284. The selection signal output unit 282 of the display IC 266 transmits the fifth selection signal to the fifth display circuit 265 through the fifth selection signal line 305. As a result, the display data supplied to all of the first to fifth display circuits 261 to 265 through the display signal group 291 and the branch signal group 292 is received and used only in the fifth display circuit 265.

FIG. 122 shows how the main CPU 63 transmits the type data and the display data to the display IC 266, and the display data transmitted from the display IC 266 is received by the first display circuit 261 or the second display circuit 262. It is a time chart. 122(a) shows a transmission period of the type data signal from the main CPU 63 to the display IC 266, FIG. 122(b) shows a transmission period of the type clock signal from the main CPU 63 to the display IC 266, and FIG. ) Indicates the transmission period of the display data signal from the main CPU 63 to the display IC 266, FIG. 122D shows the transmission period of the display clock signal from the main CPU 63 to the display IC 266, and FIG. 122E shows the display IC 266. 122(f) shows the transmission period of the second selection signal from the display IC 266 to the second display circuit 262, and FIG. 122(g) shows the transmission period of the first selection signal from the display IC to the first display circuit 261. The transmission period of the display data from the display IC 266 to the first to fifth display circuits 261 to 265 is shown. The same applies when the display data is received by the third to fifth display circuits 263 to 265.

Type data from the main CPU 63 to the display IC 266 at the timing t1 after the supply of operating power to the pachinko machine 10 including the main CPU 63, the display IC 266, and the first to fifth display circuits 261 to 265 is started. And the transmission of the display data is started. Specifically, as shown in FIG. 122(b), the pulse-like type clock signal is transmitted at each of the timing of t1, the timing of t2, the timing of t3, the timing of t4, and the timing of t5. As shown in (a), the pulsed type data signal is transmitted in correspondence with the transmission of the pulsed type clock signal at the timing of t1. As a result, the information corresponding to the first display circuit 261 is stored in the type data buffer 281 of the display IC 266.

Further, as shown in FIG. 122(d), a pulse-shaped display clock is generated at each of the timing t1, the timing t2, the timing t3, the timing t4, the timing t5, the timing t6, the timing t7, and the timing t8. A signal is transmitted, and a pulse-shaped display data signal corresponding to the transmission of the pulse-shaped display clock signal at the timing of t2, the timing of t3, the timing of t5, and the timing of t7 as shown in FIG. 122(c). Will be sent. As a result, the display data corresponding to the above information form is stored in the display data buffer 283 of the display IC 266.

Then, at the timing of t9, the transmission of the display clock signal of the 8th bit is completed as shown in FIG. 122(d), so that at the timing of t9, as shown in FIG. The selection signal output unit 282 of the display IC 266 starts transmitting the first selection signal to the first display circuit 261 corresponding to the stored type data, and at the timing of t9, as shown in FIG. 122(g). Then, the display data output unit 284 of the display IC 266 starts transmitting the display data stored in the display data buffer 283. As a result, the display data is received and used by the first display circuit 261.

After that, at the timing of t10, as shown in FIGS. 122A to 122D, the transmission of the type data and the display data from the main CPU 63 to the display IC 266 is newly started. In this case, at the timing of t10, the transmission of the first selection signal from the display IC 266 to the first display circuit 261 is stopped as shown in FIGS. The transmission of the display data to the first to fifth display circuits 261 to 265 is stopped.

For details on the new transmission of the type data and the display data, as shown in FIG. 122(b), a pulse-shaped type clock at each of the timing t10, the timing t11, the timing t12, the timing t13, and the timing t14. The signal is transmitted, and as shown in FIG. 122(a), the pulsed type data signal is transmitted corresponding to the transmission of the pulsed type clock signal at the timing of t11. As a result, the information corresponding to the second display circuit 262 is stored in the type data buffer 281 of the display IC 266.

Further, as shown in FIG. 122(d), a pulse-shaped display clock is generated at each of the timing t10, the timing t11, the timing t12, the timing t13, the timing t14, the timing t15, the timing t16, and the timing t17. The signal is transmitted, and as shown in FIG. 122(c), it corresponds to the transmission of the pulsed display clock signal at the timing of t10, the timing of t11, the timing of t12, the timing of t15, the timing of t16, and the timing of t17. Then, the pulse-shaped display data signal is transmitted. As a result, the display data corresponding to the above information form is stored in the display data buffer 283 of the display IC 266.

Then, at the timing of t18, the transmission of the display clock signal of the eighth bit is completed as shown in FIG. 122(d), so that it is stored in the type data buffer 281 at the timing of t18 as shown in FIG. 122(f). The selection signal output unit 282 of the display IC 266 starts transmitting the second selection signal to the second display circuit 262 corresponding to the classified data, and at the timing of t18, as shown in FIG. The display data output unit 284 of the display IC 266 starts transmitting the display data stored in the display data buffer 283. As a result, the display data is received and used by the second display circuit 262.

Regarding the first to fourth display circuits 261-264, only one display data is transmitted in the second timer interrupt process (FIG. 123) which is the transmission target of the display data, but regarding the fifth display circuit 265, In the second timer interrupt process (FIG. 123) that is the transmission target of the display data, four pieces of display data are transmitted corresponding to the numbers of the first to fourth notification display devices 201 to 204. The second timer interrupt process (FIG. 123) will be activated in the second interrupt cycle (specifically, 2 milliseconds) as already described, but even if it is the processing time for transmitting four display data. Each processing time is set such that one processing is completed within the second interrupt cycle.

With the above configuration, it becomes possible to transmit display data to the plurality of display circuits 261 to 265 by using one display IC 266. Here, as described above, each of the first to fifth display circuits 261 to 265 can store and hold the provided display data for a predetermined period (for example, 16 milliseconds), but the predetermined period has elapsed. Then, the display data gradually approaches the state of all "0". In this case, if the reception of the display data in each of the display circuits 261 to 265 exceeds the predetermined period, the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, the general figure reservation display unit 38b, and the special figure reservation display unit 38b. Even in a situation in which the display contents of the first to fourth notification display devices 201 to 204 are not changed, the display segments that are in the light emitting state temporarily approach the extinguished state, and as a result, the light in the display segments is changed. May flash. On the other hand, in the present embodiment, in addition to the first timer interrupt process (FIG. 117) activated in the first interrupt cycle (specifically, 4 milliseconds), the second interrupt shorter than the first interrupt cycle is executed. A second timer interrupt process (FIG. 123) activated in a cycle (specifically, 2 milliseconds) is set, and the display data is transmitted to the display IC 266 collectively in the second timer interrupt process. ..

The second timer interrupt process will be described below with reference to the flowchart of FIG. 123. Note that the processing of steps S8401 to S8413 in the second timer interrupt processing is executed using the program for specific control and the data for specific control in the main CPU 63.

First, in order to prohibit the occurrence of the first timer interrupt process (FIG. 117) and the second timer interrupt process (FIG. 123), interrupt prohibition is set (step S8401). Since the generation of the first timer interrupt process (FIG. 117) is prohibited, the first timer interrupt process (FIG. 117) interrupts the second timer interrupt process (FIG. 123) even if the first interrupt cycle has elapsed. It is possible to prevent it from being started with. Further, since the generation of the second timer interrupt process (FIG. 123) is prohibited, even if the second interrupt cycle elapses during the execution of the second timer interrupt process (FIG. 123), the second timer interrupt process is performed. It is possible to prevent the processing (FIG. 123) from being redundantly activated.

After that, it is determined whether the setting update display flag in the specific control work area 221 is set to "1" (step S8402). The setting update display flag is a flag for the main CPU 63 to specify whether or not the setting value update processing (FIG. 116) is being executed by the main CPU 63. As described above, the set value updating process (FIG. 116) is performed in the main process (FIG. 114) when the supply of the operating power to the main CPU 63 is started and the process at the start of supplying the operating power is executed. Although it will be executed, the second timer interrupt process (FIG. 123) is activated by interruption even if the process at the start of supply of the operating power is being executed. The second timer interrupt process (FIG. 123) is activated by interruption even when the value update process (FIG. 116) is being executed.

The situation in which the setting update display flag is set to "1" means that the main CPU 63 is executing the setting value update processing (FIG. 116) for the current processing time of the second timer interrupt processing (FIG. 123). It means that the process is started by interrupting the situation. If an affirmative decision is made in step S8402, setting processing for the fifth display data buffer 275 during the setting update is executed (step S8403). In the setting process, a display showing that the setting values of the pachinko machine 10 are being updated on the first to fourth notification display devices 201 to 204 and a display showing the current setting values of the pachinko machine 10. The display data to be executed is stored in the fifth display data buffer 275.

When the display data stored in the fifth display data buffer 275 is transmitted to the fifth display circuit 265 via the display IC 266, the description of FIG. 124(a) is made for the first to fourth notification display devices 201 to 204. The display shown in the figure is performed. Specifically, when a display indicating that the setting value is being updated is displayed on the first to fourth notification display devices 201 to 204, the first to fourth notification display devices 201 to 204 are displayed. At least one display segment is in a light emitting state in each. That is, each of the first to fourth notification display devices 201 to 204 is in a display state. As a result, even if a display indicating that the setting value is being updated is being displayed, the fact that the first to fourth notification display devices 201 to 204 have not failed is displayed in the game hall. The administrator can grasp it. Even when the management result of the game history is displayed, at least one display segment in each of the first to fourth notification display devices 201 to 204 is in a light emitting state, and the first to fourth notifications are performed. Each of the display devices 201 to 204 is in a display state.

For details of the display contents of each of the first to fourth notification display devices 201 to 204, in the first notification display device 201, one central display segment is in a light emitting state and the remaining display segments are in a non-lighting state. Becomes Even when the management result of the game history is displayed on the first to fourth notification display devices 201 to 204, one central display segment in the first notification display device 201 can be in a light emitting state, When the management result of the game history is displayed, the display content of the first notification display device 201 includes the display content in which one display segment at the center is in the light emitting state and the remaining display segments are in the off state. Not not. Thereby, the display contents of the first notification display device 201 in the situation where the setting value is updated while using the display segment that can be in the light emitting state even when the management result of the game history is displayed It is possible to make the display contents not displayed in the management result of.

In the second notification display device 202, as in the case of the first notification display device 201, one central display segment is in a light emitting state and the remaining display segments are in a non-lighting state. Even when the management result of the game history is displayed on the first to fourth notification display devices 201 to 204, one display segment in the center of the second notification display device 202 can be in a light emitting state, The display content of the second notification display device 202 when the game history management result is displayed includes the display content in which one display segment in the center is in the light emitting state and the remaining display segments are in the off state. Not not. Thereby, the display contents of the second notification display device 202 in the situation where the set value is updated while using the display segment that can be in the light emitting state even when the management result of the game history is displayed It is possible to make the display contents not displayed in the management result of.

On the third annunciator display device 203, some of the display segments are in a light emitting state and the remaining display segments are in an off state so that the character “H” is displayed. In this case, the display segment in the light emitting state can be in the light emitting state even when the game history management results are displayed on the first to fourth notification display devices 201 to 204, but the game history management result is When displayed, the display content of the third notification display device 203 does not include the display content in which the character “H” is displayed. As a result, the display contents of the third notification display device 203 in the situation where the setting value is updated while using the display segment that can be in the light emitting state even when the management result of the game history is displayed are displayed as the game history. It is possible to make the display contents not displayed in the management result of. Further, the display content of the third notification display device 203 in the situation of confirming the set value does not include the display content in which the character “H” is displayed. Thus, by displaying "H" on the third notification display device 203, it is possible to notify the manager of the game hall that the setting value is being updated.

On the fourth annunciator display device 204, some display segments are in a light emitting state and the remaining display segments are in an off state so that the display corresponding to the current set value is performed. In the case of FIG. 124(a), the current setting value is “setting 2”, and thus “2” corresponding to “setting 2” is displayed on the fourth notification display device 204. By checking the fourth notification display device 204, the game hall manager can grasp the current set value. Note that the display content of the fourth notification display device 204 in the situation where the setting value is updated can be displayed in both the situation in which the management result of the game history is displayed and the situation in which the setting value is being confirmed.

Returning to the explanation of the second timer interrupt process (FIG. 123), if a negative decision is made in step S8402, it is decided whether or not “1” is set in the setting confirmation display flag in the work area 221 for specific control. (Step S8404). The setting confirmation display flag is a flag for the main CPU 63 to specify whether or not the setting confirmation processing (FIG. 115) is being executed by the main CPU 63. As described above, the setting confirmation process (FIG. 115) is performed in the main process (FIG. 114) when the supply of the operating power to the main CPU 63 is started and the process at the start of the supply of the operating power is executed. Although it will be executed, the second timer interrupt process (FIG. 123) is activated by interruption even if the process at the start of supply of the operating power is being executed. The second timer interrupt processing (FIG. 123) is activated by interruption even in the situation where the confirmation processing (FIG. 115) is being executed.

The situation where the setting confirmation display flag is set to "1" means that the main CPU 63 is executing the setting confirmation processing (FIG. 115) for the current processing time of the second timer interrupt processing (FIG. 123). It means that the processing time was interrupted and activated in some situations. If an affirmative decision is made in step S8404, setting processing for the fifth display data buffer 275 during setting confirmation is executed (step S8405). In the setting process, a display indicating that the setting value of the pachinko machine 10 is being confirmed on the first to fourth notification display devices 201 to 204 and a display indicating the current setting value of the pachinko machine 10 are displayed. The display data to be executed is stored in the fifth display data buffer 275.

When the display data stored in the fifth display data buffer 275 is transmitted to the fifth display circuit 265 via the display IC 266, the first to fourth notification display devices 201 to 204 will be described with reference to FIG. The display shown in the figure is performed. Specifically, when a display indicating that the setting value is being updated is displayed on the first to fourth notification display devices 201 to 204, the first to fourth notification display devices 201 to 204 are displayed. At least one display segment is in a light emitting state in each. That is, each of the first to fourth notification display devices 201 to 204 is in a display state. As a result, even when the display indicating that the setting value is being confirmed is being displayed, it is confirmed that the first to fourth notification display devices 201 to 204 have not failed in the game hall. The administrator can grasp it.

For details of the display contents of each of the first to fourth notification display devices 201 to 204, in the first notification display device 201, one central display segment is in a light emitting state and the remaining display segments are in a non-lighting state. Becomes Even when the management result of the game history is displayed on the first to fourth notification display devices 201 to 204, one central display segment in the first notification display device 201 can be in a light emitting state, When the management result of the game history is displayed, the display content of the first notification display device 201 includes the display content in which one display segment at the center is in the light emitting state and the remaining display segments are in the off state. Not not. As a result, the display contents of the first notification display device 201 in the situation of confirming the set value while using the display segment that can be in the light emitting state even when the management result of the game history is displayed are displayed as the game history. It is possible to have display contents that are not displayed in the management result of.

In the second notification display device 202, as in the case of the first notification display device 201, one central display segment is in a light emitting state and the remaining display segments are in a non-lighting state. Even when the management result of the game history is displayed on the first to fourth notification display devices 201 to 204, one display segment in the center of the second notification display device 202 can be in a light emitting state, The display content of the second notification display device 202 when the game history management result is displayed includes the display content in which one display segment in the center is in the light emitting state and the remaining display segments are in the off state. Not not. Thereby, the display contents of the second notification display device 202 in the situation where the set value is confirmed while using the display segment that can be in the light emitting state even when the management result of the game history is displayed It is possible to have display contents that are not displayed in the management result of.

Here, the display contents on the first notification display device 201 and the second notification display device 202 are the same whether the setting value is being updated or the setting value is being confirmed. As a result, that the display target on the first to fourth notification display devices 201 to 204 is not related to the management result of the game history but is related to the set value, the first notification display device 201 and the second notification display device 202. With this display, it becomes possible to clearly inform the manager of the game hall.

On the third annunciator display device 203, some of the display segments are in a light emitting state and the remaining display segments are in an off state so that the character "k" is displayed. In this case, the display segment in the light emitting state can be in the light emitting state even when the game history management results are displayed on the first to fourth notification display devices 201 to 204, but the game history management result is The display content of the third notification display device 203 when being displayed does not include the display content of displaying the character “k”. As a result, the display contents of the third notification display device 203 in the situation of confirming the set value while using the display segment that can be in the light emitting state even when the management result of the game history is displayed are displayed in the game history. It is possible to make the display contents not displayed in the management result of. Further, “H” is displayed on the third notification display device 203 when the setting value is being updated, whereas “k” is displayed on the third notification display device 203 when the setting value is being confirmed. Is displayed. Thus, by confirming the display content of the third notification display device 203, the manager of the game hall is notified of whether the setting value is being updated or the setting value is being confirmed. It becomes possible.

On the fourth annunciator display device 204, some display segments are in a light emitting state and the remaining display segments are in an off state so that the display corresponding to the current set value is performed. In the case of FIG. 124B, since the current setting value is “setting 2”, “2” corresponding to “setting 2” is displayed on the fourth notification display device 204. By checking the fourth notification display device 204, the game hall manager can grasp the current set value. The display content of the fourth notification display device 204 in the situation of confirming the set value can be displayed in both the situation in which the management result of the game history is displayed and the situation in which the set value is updated.

Returning to the explanation of the second timer interrupt process (FIG. 123), if a negative decision is made in step S8404, the setting process to the fifth display data buffer 275 in the normal time is executed (step S8406). In this case, information is read from the display target setting area 276 in the work area 223 for non-specific control, and the parameters corresponding to the read information are displayed on the first to fourth notification display devices 201 to 204. The display data is stored in the fifth display data buffer 275. By transmitting the display data to the fifth display circuit 265 via the display IC 266, the first to fourth notification display devices 201 to 204 calculate the current display target parameter among the 61st to 68th parameters. The result is displayed.

When the process of step S8403, step S8405 or step S8406 is executed, the signal transmission state through the type data signal line LN1 and the type clock signal line LN2 is set to the OFF state (step S8407), and the display data signal line LN3 and the display are displayed. The transmission state of the signal through the clock signal line LN4 is turned off (step S8408). After that, update processing of the type counter provided in the work area 221 for specific control is executed (step S8409).

The type counter is a counter for the main CPU 63 to specify the transmission target of display data among the first to fifth display data buffers 271 to 275 in the current processing time of the second timer interrupt processing. When the value of the type counter is "1", the display data of the first display data buffer 271 is the transmission target, and when the value of the type counter is "2", the display data of the second display data buffer 272 is the transmission target. When the value of the type counter is “3”, the display data of the third display data buffer 273 is the transmission target, and when the value of the type counter is “4”, the display data of the fourth display data buffer 274 is When it becomes a transmission target and the value of the type counter is “5”, the display data of the fifth display data buffer 275 becomes a transmission target. In the type counter update process, the value of the type counter is incremented by 1, and if the value of the type counter after adding 1 exceeds the upper limit value of "5", the value of the type counter is set to "1". .. As a result, the transmission target of display data is sequentially changed in the first to fifth display data buffers 271 to 275 for each processing time of the second timer interrupt processing.

After that, the type data corresponding to the value of the type counter is read from the main ROM 64 (step S8410). Specifically, when the value of the type counter is "1", the type data corresponding to the first display circuit 261 is read from the main ROM 64, and when the value of the type counter is "2", the second type data is read. The type data corresponding to the display circuit 262 is read from the main ROM 64, and when the type counter value is “3”, the type data corresponding to the third display circuit 263 is read from the main ROM 64 and the type counter value is When it is "4", the type data corresponding to the fourth display circuit 264 is read from the main ROM 64, and when the type counter value is "5", the type data corresponding to the fifth display circuit 265 is mainly read. Read from the side ROM 64.

Then, the display data is read from the display data buffers 271-275 corresponding to the value of the type counter (step S8411). Specifically, when the value of the type counter is "1", the display data is read from the first display data buffer 271, and when the value of the type counter is "2", the second display data buffer 272 is read. When the display data is read and the value of the type counter is “3”, the display data is read from the third display data buffer 273, and when the value of the type counter is “4”, the fourth display data buffer 274 is read. The display data is read, and when the value of the type counter is "5", the display data is read from the fifth display data buffer 275.

After that, transmission processing of various signals is executed (step S8412). In the transmission processing, signals are output to the type data signal line LN1 and the type clock signal line LN2 so that the type data read in step S8410 is transmitted to the display IC 266. Further, in the transmission process, signals are output to the display data signal line LN3 and the display clock signal line LN4 so that the display data read in step S8411 is transmitted to the display IC 266.

After that, interrupt permission is set to permit the generation of the first timer interrupt process (FIG. 117) and the second timer interrupt process (FIG. 123) (step S8413).

According to this embodiment described in detail above, the following excellent effects are exhibited.

By turning on the power of the pachinko machine 10 with the setting key insertion portion 68a turned on by the setting key without pressing the reset button 68c, supply of operating power to the main CPU 63 is started. In the situation where the main process (FIG. 114) is started, the reset button 68c is not pressed and the setting key insertion part 68a is turned on, and the process for allowing the progress of the game is executed in the main process. The setting confirmation process is executed in a condition before the operation power supply start, which is a condition before the setting. As a result, it becomes possible to make it difficult to perform an act of illegally confirming the set value.

Assuming that the setting value is confirmed in the situation where the game continues, for example, if the setting value is confirmed during the execution of the game times, the setting value is being confirmed. Therefore, there is a possibility that the switching to the open/close execution mode may occur. In this case, there is a possibility that the game ball cannot be fired toward the special electric prize winning device 32 even though the opening/closing execution mode is started. Further, if the set value is confirmed during the execution of the opening/closing execution mode, the opening/closing execution mode will proceed under the situation where the setting value is being confirmed. It may not be possible to shoot a game ball toward.

Assuming that the progress of the game is stopped when the setting value is confirmed, if the setting value confirmation is started in the situation where the game is being performed, the progress of the game is stopped midway. Processing may be complicated. For example, when the confirmation of the set value is started during the execution of the game time and the progress of the game is to be stopped midway, a process for stopping the game time is required. In this case, when the confirmation of the set value is started, the variable display of the symbol on the symbol display device 41 is stopped midway, and when the confirmation of the set value is completed, the variable display of the symbol on the symbol display device 41 is restarted. If so, complicated processing is required. In addition, for example, when the confirmation of the set value is started during the execution of the opening/closing execution mode and it is attempted to stop the progress of the game on the way, a process for stopping the opening/closing execution mode is required. Further, when the setting value confirmation is started during the execution of the variable display of the pattern on the public figure display unit 38a and the game progress is to be stopped midway, the process for stopping the variable display of the pattern is performed. Will be required. Further, if the setting value confirmation is started during the execution of the open execution state of the general electric auditors a and the progress of the game is to be stopped midway, a process for stopping the open execution state is required. Become. On the other hand, a configuration may be considered in which the setting value is confirmed by waiting until all the games are completed, but in this case, the game times, the opening/closing execution mode, the variable display of the pattern on the normal figure display portion 38a, and the normal electric combination Since it is necessary to wait until a state in which none of the open execution states of the object 34a is executed is executed, there is a possibility that the waiting time until the confirmation of the set value is started becomes long.

On the other hand, in the main process executed when the supply of the operating power to the main CPU 63 is started, when the supply of the operating power is the situation before the process that allows the progress of the game is executed. Since the setting confirmation processing is executed in the situation where the processing is being executed, the setting value is confirmed in the situation where the progress of the game is already stopped. As a result, it is possible to prevent the setting value from being confirmed while the game is in progress, and to stop the progress of the game midway when confirming the set value, or to stop the progress of the game. There is no need to wait for confirmation of the set value until Therefore, it becomes possible to properly confirm the set value.

When the power of the pachinko machine 10 is turned on while pressing the reset button 68c, supply of operating power to the main CPU 63 is started and the main process (FIG. 114) is started. Is pressed, and the RAM clearing process (step S7915) is executed regardless of whether the setting key insertion portion 68a is turned ON. As a result, the operation content of turning on the power of the pachinko machine 10 while pressing the reset button 68c is uniquely linked to the execution of the RAM clear processing (step S7915), and the RAM clear processing (step S7915). It becomes possible for the manager of the game hall to easily understand the operation content for generating.

Even if the RAM clearing process (step S7915) is executed, the set value counter in the specific control work area 221 is not cleared to "0" and the set value counter information is not changed. This makes it possible to prevent the set value from being changed even if the RAM clear process (step S7915) is executed.

Based on not only turning on the power of the pachinko machine 10 while pressing the reset button 68c, but also turning on the power of the pachinko machine 10 while turning on the setting key insertion portion 68a with the setting key, the RAM Not only the clearing process (step S7915) but also the set value updating process (step S7918) is executed. In addition, as described above, the setting confirmation processing is performed based on the operation of turning on the power of the pachinko machine 10 while the setting key insertion portion 68a is turned on by the setting key without pressing the reset button 68c (step S7914). Is executed. As a result, it becomes possible to make the ON operation for the setting key insertion unit 68a common as the operation for executing the process related to the set value. Therefore, it becomes possible for the manager of the game hall to easily understand the operation content for generating the processing related to the set value.

When the power of the pachinko machine 10 is turned on while the setting key insertion portion 68a is turned on by the setting key, and the pressing operation of the reset button 68c is not added, the setting confirmation processing is executed and the reset button When the pressing operation of 68c is added, the set value updating process is executed. As a result, it becomes possible to make the setting confirmation process and the setting value update process different from each other depending on whether or not the reset button 68c is pressed. Therefore, it becomes possible for the manager of the game hall to easily understand the operation content for executing the desired processing among the setting confirmation processing and the setting value updating processing. Further, by increasing the number of operations for executing the setting value updating process more than the setting confirming process, it becomes possible to make it particularly difficult to illegally perform the setting value updating process.

The monitoring process for determining whether or not the set value is abnormal is executed by the first timer interrupt process (FIG. 117) that is regularly activated. Thereby, it becomes possible to monitor whether or not the set value is abnormal even in a situation where a game is being played. Therefore, it is possible to prevent the game from being continued even if the set value is abnormal.

The monitoring of whether or not the set value is abnormal is executed every time a monitoring trigger occurs. More specifically, it is executed every time the first timer interrupt process (FIG. 117) is started. As a result, it is possible to increase the frequency of monitoring whether the set value is abnormal.

In the main process (FIG. 114), the process for monitoring whether or not the set value is normal is not set. When the process for monitoring whether or not the set value is normal is set in the process at the start of supplying the operating power in the main process (FIG. 114), the power failure flag and the checksum are set at the start of supplying the operating power. It becomes necessary to monitor whether or not the set value is normal, in addition to the above-mentioned monitoring, which increases the monitoring load. Further, when it is determined that the set value is abnormal at the start of the supply of the operating power, the RAM clear process (step S7915) and the set value update process (step S7918) are attempted to be executed. Becomes complicated. On the other hand, since the process for monitoring whether the set value is normal is not set in the main process (FIG. 114), the processing configuration of the process at the start of supplying the operating power is preferable. It becomes possible. Even if the process for monitoring whether or not the set value is normal is not set in the process at the start of supplying the operating power as described above, the setting monitoring is performed by the first timer interrupt process (FIG. 117). Since the processing (step S8220) is executed, it is possible to deal with the abnormal set value.

According to the display data transmitted from the main CPU 63, the display IC 266 performs the display setting for the first to fifth display circuits 261 to 265, so that the display contents corresponding to the display data become the special figure display portion 37a. , The special figure reservation display unit 37b, the general figure display unit 38a, the general figure reservation display unit 38b, and the first to fourth notification display devices 201 to 204 are display-controlled. This makes it possible to reduce the processing load on the main CPU 63. In this case, a plurality of display units such as the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, the general figure reservation display unit 38b, and the first to fourth notification display devices 201 to 204 are provided. In the provided configuration, the display ICs 266 are not provided in a one-to-one correspondence with the plurality of display units, but one display IC 266 is also used for the plurality of display units. This makes it possible to increase the number of display units to be display-controlled while suppressing the increase in the number of display ICs 266. In addition, the transmission interval of the display data from the main CPU 63 to the display IC 266 is set to the display circuits 261 to 265 corresponding to the respective display units before the display corresponding to the display data cannot be maintained in each display unit. The display interval is set by the display IC 266. Accordingly, even in a configuration in which one display IC 266 is also used for a plurality of display units, it is possible to appropriately perform display corresponding to display data on each display unit.

When transmitting the display data to the display IC 266, the main CPU 63 transmits to the display IC 266 the type data that makes it possible to specify the type of the display circuits 261 to 265 to which the display data is set. Thus, when the display data is transmitted from the main CPU 63, the display IC 266 may set the display data to the display circuits 261 to 265 corresponding to the type data transmitted from the main CPU 63. Therefore, even if one display IC 266 is also used for a plurality of display portions, the structure of the display IC 266 can be simplified.

The main CPU 63 transmits the display data so that the update cycle is repeated when the plurality of display units are set as the display data setting objects once in the predetermined order as one update cycle. I do. As a result, the main CPU 63 only needs to change the display unit to which the display data is transmitted in accordance with a predetermined order, so that the processing configuration of the main CPU 63 can be simplified.

Even when the content of the display data for one display unit is the same as the content of the display data when the display unit was previously transmitted as the transmission target, the main CPU 63 determines that the display unit is the transmission target. Sends the display data. This makes it possible to continue the same display on a predetermined display unit even if one display IC 266 is also used for a plurality of display units.

The main CPU 63 executes a process for transmitting display data to the display IC 266 by a second timer interrupt process (FIG. 123) which is activated by interrupting another process when the second interrupt cycle is reached. This makes it possible to set the cycle in which the display data is set on each display unit to a predetermined cycle. Therefore, even in the configuration in which one display IC 266 is also used for a plurality of display units, the display corresponding to the display data cannot be maintained in each display unit before each display unit can be maintained. It becomes possible to set the display data by the display IC 266.

The processing for transmitting the display data to the first to fifth display circuits 261 to 265 which are the objects of the display setting by the display IC 266 is summarized in the second timer interrupt processing (FIG. 123). As a result, it is possible to set the cycle in which the display data is set in the first to fifth display circuits 261 to 265 to be the same cycle.

When the first interrupt cycle comes, the main CPU 63 interrupts other processing and executes the first timer interrupt processing (FIG. 117). In this case, the second interrupt cycle of the second timer interrupt process (FIG. 123) is set to be shorter than the first interrupt cycle of the first timer interrupt process (FIG. 117). As a result, the display data can be transmitted in a shorter cycle than the configuration in which the process of transmitting the display data to the display IC 266 is executed by the first timer interrupt process (FIG. 117).

In addition, the process of transmitting the display data to the display IC 266 is set in the second timer interrupt process (FIG. 123) whose interrupt cycle is shorter than the first timer interrupt process (FIG. 117) in which the process for advancing the game is set. Has been done. As a result, the first timer interrupt process (FIG. 117) is activated at an appropriate cycle in executing the process for advancing the game, and it is possible to obtain the excellent effect as already described. Become.

The second timer interrupt process (FIG. 123) is started by interrupting even when the first timer interrupt process (FIG. 117) is being executed. As a result, the display data transmission cycle can be set to a predetermined cycle.

When the second timer interrupt process (FIG. 123) is started, the interrupt of the first timer interrupt process (FIG. 117) is prohibited, and when the second timer interrupt process (FIG. 123) is ended, the first timer interrupt process The interrupt of FIG. 117 is enabled. As a result, it is possible to prevent the first timer interrupt process (FIG. 117) from being interrupted and executed while the second timer interrupt process (FIG. 123) is being executed. Therefore, it becomes possible to prioritize the process for transmitting the display data.

The second timer interrupt process (FIG. 123) is activated even if the process (steps S7901 to S7918) at the start of supplying the operating power is being executed in the main process (FIG. 114). This makes it possible to control the display of a plurality of display units even in the situation where the process at the start of supplying the operating power is being executed. Further, since the second timer interrupt process (FIG. 123) is activated by interrupting the process at the start of the supply of the operating power, the process configuration of the process at the start of the supply of the operating power is not complicated. Also, it becomes possible to control the display of a plurality of display units in a situation where the process at the start of supplying the operating power is being executed.

The second timer interrupt process (FIG. 123) is also interrupted and activated even in the situation where the setting value update process (step S7918) is being executed in the main process (FIG. 114), and in that situation, the second timer interrupt process is performed. In (FIG. 123), the display data for displaying the current set value on the fourth notification display device 204 is transmitted. As a result, the current set value is displayed on the fourth notification display device 204 in the situation where the set value updating process (step S7918) is being executed without complicating the processing configuration of the main process (FIG. 114). It is possible to do so.

Even after the process at the start of supply of operating power is executed in the main process (FIG. 114), the second timer interrupt process (FIG. 123) is activated every time the second interrupt period elapses. Thus, by using the second timer interrupt process (FIG. 123), whether the process at the time of starting the supply of the operating power is being executed or the condition after the process at the start of supplying the operating power is finished Also in this case, it is possible to control the display of a plurality of display units.

An update button 68b is provided as in the first embodiment, and in the set value update process (FIG. 116), the set value may be updated by one step each time the reset button 68c is pressed. Instead, the set value may be updated by one step each time the update button 68b is pressed. Further, the position corresponding to each of "Setting 1" to "Setting 6" is set as the rotation operation position when the setting key is inserted into the setting key insertion portion 68a and the rotation operation is performed. A set value corresponding to the rotational operation position of the portion 68a may be set. Further, the setting key insertion portion 68a is configured to be able to be rotated further than the ON position, and each time the rotating operation beyond the ON position is performed, the set value being updated becomes the set value in the next order. The configuration may be updated.

Further, in the set value updating process (FIG. 116), the set value being selected is confirmed by turning off the setting key insertion portion 68a, and the set value updating process is finished by further pressing the reset button 68c. It may be configured to be. Further, in the configuration in which the update button 68b is provided, in the set value update processing (FIG. 116), the set value being selected is confirmed by turning off the set key insertion portion 68a, and the update button 68b is further pressed. The configuration may be configured such that the setting value updating process is ended by an operation.

Further, as the condition for executing the set value updating process (FIG. 116), the condition that the gaming machine main body 12 is in the open state may not be set, and the front door frame 14 is in the open state. It may be configured such that the condition that the game machine body 12 is in the open state and the condition that the front door frame 14 is in the open state are not set.

Further, as the condition for executing the setting confirmation process (FIG. 115), the condition that the gaming machine main body 12 is in the open state may not be set, and the front door frame 14 is in the open state. It may be configured such that the condition that the game machine body 12 is in the open state and the condition that the front door frame 14 is in the open state are not set.

Further, it is specified that "1" is not set in the power failure flag or the checksum is abnormal in the main process (FIG. 114) executed when the supply of the operating power to the main CPU 63 is started. In this case, the RAM clearing process (step S7915) may be executed. In this case, the setting clearing process (step S7918) may be executed after the RAM clearing process (step S7915) is executed, and a notification indicating that the setting value updating process (step S7918) should be executed is given. May be configured to stop the progress of the game while executing, and the configuration to start the process for controlling the progress of the game.

Further, instead of the configuration in which the setting confirmation process (step S7914) in the main process (FIG. 114) is executed after the determination process of whether or not the power failure flag is set to “1” and the checksum comparison process. The configuration may be executed before these processes. In this case, it is possible to give priority to the processing for confirming the set value.

Further, the setting monitoring process (step S8220) is not limited to the configuration executed every time the first timer interrupt process (FIG. 117) is activated. The setting monitoring process (step S8220) may be executed every time the predetermined number of triggers (for example, 10,000 times) is executed. In this case, it is possible to suppress the frequency of execution of the monitoring while regularly monitoring whether or not the set value is normal.

Further, the setting monitoring process (step S8220) may be executed by the residual process (steps S7921 to S7924) in the main process (FIG. 114). In this case, it is possible to monitor whether or not the set value is normal by utilizing the free time in the situation where the first timer interrupt process (FIG. 117) and the second timer interrupt process (FIG. 123) are not executed. It will be possible.

Further, the setting monitoring process (step S8220) may be executed when the game time is newly started. More specifically, the setting monitoring process (step S8220) may be executed before the win/loss determination process is executed when the game time is newly started. As a result, it is possible to prevent the success/failure determination process from being executed when the set value is abnormal.

Further, when it is specified that the set value is abnormal in the setting monitoring process (step S8220), the process may shift to the set value updating process (step S7918).

When it is determined that the setting value is abnormal in the setting monitoring process (step S8220), the main process (“1”) is set in the setting abnormal flag provided in the work area 221 for specific control. 114) may be started, and in order to stop the progress of the game with the setting abnormality flag set to "1" and release the state where the progress of the game is stopped, the power is turned off. It may be configured to require ON. In this case, in the main process (FIG. 114), even if the operation for executing the set value updating process is not performed, if the setting abnormality flag is set to “1”, the setting is forcibly set. By executing the value update process, it is possible to force the new setting of the set value by using the set value update process set in the main process (FIG. 114).

In addition, the hold information acquired when the game ball enters the first operating port 33 and the hold information acquired when the game ball enters the second operating port 34 are stored separately. The special figure display section 37a may have a configuration in which a first special figure display section and a second special figure display section are provided in correspondence with the reservation information. In this case, the variable display of the pattern on the first special figure display part and the variable display of the pattern on the second special figure display part can be executed in an overlapping manner, and when either one of the predetermined game states is reached, either The duration of variable display of patterns on the special figure display portion may be extremely long. In the configuration, if the player waits for confirmation of the set value until the game is not played, the waiting time becomes long. On the other hand, by performing the setting confirmation process (step S7914) in the process at the time of starting the supply of the operating power in the main CPU 63, the set value can be set without causing the waiting time as described above. It becomes possible to confirm.

Further, in the low frequency support mode, the duration of the variable display of the picture on the general figure display unit 38a may be extremely long. In the configuration, if the player waits for confirmation of the set value until the game is not played, the waiting time becomes long. On the other hand, by performing the setting confirmation process (step S7914) in the process at the time of starting the supply of the operating power in the main CPU 63, the set value can be set without causing the waiting time as described above. It becomes possible to confirm.

Further, the display contents of the first to fourth notification display devices 201 to 204 in the case where the setting confirmation process (FIG. 115) is executed are not limited to the display contents in the above embodiment, and for example, the third notification Instead of displaying the character “k” on the display device 203 for display, only the central display segment may be in the light emitting state like the first display device 201 for notification and the second display device 202 for notification. .. Further, the first to third notification display devices 201 to 203 may be turned off, and the fourth notification display device 204 may be configured to perform a display corresponding to the current set value.

Further, the display contents of the first to fourth notification display devices 201 to 204 in the case where the set value updating process (FIG. 116) is executed are not limited to the display contents in the above-described embodiment. Instead of displaying the character “H” on the display device 203 for display, only the central display segment may be in the light emitting state like the first display device 201 for notification and the second display device 202 for notification. .. Further, the first to third notification display devices 201 to 203 may be turned off, and the fourth notification display device 204 may be configured to perform a display corresponding to the current set value.

Further, the main CPU 63 may have a configuration in which, instead of simultaneously transmitting the type data and the display data to the display IC 266, the transmission of the display data is started after the transmission of the type data is started. In this case, the display data may be transmitted while the type data is being transmitted, or the display data may be transmitted after the type data is completely transmitted. Further, the configuration may be such that the transmission of the type data is started after the transmission of the display data is started. In this case, the type data transmission may be started during the display data transmission, or the type data transmission may be started after the display data transmission is completed.

Further, the display IC 266 is not limited to the configuration in which only one display IC is provided so as to be common to the first to fifth display circuits 261 to 265. The configuration may be such that they are provided in a one-to-one correspondence with each other. In this configuration, when the display data stored in each display IC provided in a one-to-one correspondence with the first to fifth display circuits 261 to 265 is short, the display data to each display IC is Depending on the providing cycle, there is a possibility that unintentional blinking may occur on each display unit. On the other hand, by consolidating the processing for transmitting the display data to the second timer interrupt processing (FIG. 123) having a relatively short interrupt cycle as in the above-described embodiment, the display data of each display IC can be displayed. The provision cycle can be shortened, and it is possible to prevent unintentional blinking from occurring in each display unit.

Further, instead of the configuration in which the winning random number counter C1 is provided in the main RAM 65, a configuration may be provided in which a random number circuit for updating the random number acquired in the hit/miss determination processing is provided. In this case, in the internal function register setting process in the main process (FIG. 114), settings are made to associate the random number of the random number circuit with the random number acquired in the hit/miss determination process.

In the first timer interrupt process (FIG. 117), the timer interrupt process is prohibited and the timer interrupt process is permitted before and after each process of steps S8201 to S8221, but this may be changed. For example, for some processes of the first timer interrupt process (FIG. 117), the timer interrupt process is prohibited and the timer interrupt process is permitted before and after the process, while other processes of the first timer interrupt process (FIG. 117) are performed. With regard to the above, the configuration may be such that the timer interrupt processing is not prohibited and the timer interrupt processing is not permitted before and after that. Further, it may be configured such that a plurality of processes included in the first timer interrupt process (FIG. 117) are sandwiched between the prohibition of the timer interrupt process and the permission of the timer interrupt process.

Further, in the first timer interrupt processing (FIG. 117), the setting for prohibiting the interrupt of the second timer interrupt processing (FIG. 123) may not be performed. In this case, since the second timer interrupt process (FIG. 123) is executed with priority over the first timer interrupt process (FIG. 117), it is possible to give priority to the display control of the plurality of display units. .. Further, in the configuration, in the first timer interrupt process (FIG. 117), the interrupt of the first timer interrupt process (FIG. 117) is prohibited in order to prevent the first timer interrupt process (FIG. 117) from being activated in duplicate. On the other hand, the interrupt of the second timer interrupt processing (FIG. 123) may not be prohibited.

When both the first timer interrupt process (Fig. 117) and the second timer interrupt process (Fig. 123) are triggered, the second timer interrupt process (Fig. 123) is executed as the first timer interrupt process (Fig. 123). 117), the first timer interrupt processing (FIG. 117) may be prioritized over the second timer interrupt processing (FIG. 123) instead of the prioritized execution. The timer interrupt processing may be started earlier in the order of occurrence.

Further, in the situation where the second timer interrupt process (FIG. 123) is being executed, the second timer interrupt process (FIG. 123) is executed instead of the configuration in which the execution of the first timer interrupt process (FIG. 117) is prohibited. Even in the situation where the first timer interrupt process (FIG. 117) is activated, the first timer interrupt process (FIG. 117) may be activated. This makes it possible to give priority to execution of processing for advancing a game over display control of a plurality of display units.

Further, the second timer interrupt process (FIG. 123) is not set, and various processes of the second timer interrupt process (FIG. 123) are the main process (FIG. 114) and the first timer interrupt process (FIG. 117), respectively. It may be configured to be distributed and executed in. For example, in the setting confirmation processing (step S7914) in the main processing (FIG. 114), a display indicating that the setting is being confirmed and a display corresponding to the current setting value are displayed in the first to fourth notification display devices 201 to 204. It is also possible to adopt a configuration in which the processing for performing the above is set. Further, in the setting value updating process (step S7918) in the main process (FIG. 114), a display indicating that the setting is being updated and a display corresponding to the current setting value are displayed in the first to fourth notification display devices 201 to 204. It is also possible to adopt a configuration in which the processing for performing the above is set. Further, in the first timer interrupt process (FIG. 117), the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, the general figure reservation display unit 38b, and the first to fourth notification display devices 201 to 201. The configuration may be such that processing for controlling display of 204 is set.

Further, the second timer interrupt process (FIG. 123) is not limited to the configuration in which only the process for controlling the display of the plurality of display units is executed, and in addition to the process for controlling the display of the plurality of display units, Alternatively, or alternatively, a process different from the process for controlling the display of the plurality of display units may be executed. For example, a part of the process for advancing the game may be executed by the first timer interrupt process (FIG. 117), and the rest may be executed by the second timer interrupt process (FIG. 123). In this case, the processing in which the execution cycle is preferably shorter is executed by the second timer interrupt processing (FIG. 123) in which the interruption cycle is relatively shorter, and the processing does not cause a problem even if the execution cycle is relatively long. Is preferably executed by the first timer interrupt process (FIG. 117) having a relatively long interrupt cycle. Also, of the processes of steps S8202 to S8221 in the first timer interrupt process (FIG. 117) of the above embodiment, the power failure information storage process (step S8202) is executed by the second timer interrupt process (FIG. 123), and A process other than the above may be configured to be executed by the first timer interrupt process (FIG. 117). In this case, it is possible to repeatedly execute power failure monitoring with a relatively short cycle. In addition to or in place of the configuration, the fraud detection process (step S8206) is executed by the second timer interrupt process (FIG. 123), and the other processes are executed by the first timer interrupt process (FIG. 117). It may be configured to be. In this case, fraud monitoring can be repeatedly executed at a relatively short cycle.

Further, the number of the display circuits 261 to 265 to which the display data is set to be displayed by the display IC 266 is not limited to five, and may be two, three, four, or six or more. Good. Further, the first to fourth notification display devices 201 to 204 are not limited to the configuration in which the first to fourth notification display devices 201 to 204 are associated with the fifth display circuit 265. The display circuits may be provided in a one-to-one correspondence.

<34th Embodiment>
In this embodiment, the processing configuration of the setting value update processing executed by the main CPU 63 is different from that in the 33rd embodiment. The configuration different from that of the 33rd embodiment will be described below. The description of the same configuration as the thirty-third embodiment is basically omitted. Further, in this embodiment, the update button 68b is provided on the main control board 61 as in the first embodiment.

FIG. 125 is a flowchart showing the setting value update processing in this embodiment executed by the main CPU 63. Note that the processing of steps S8501 to S8508 in the setting value update processing is executed using the program for specific control and the data for specific control in the main CPU 63.

First, "1" is set to the setting update display flag provided in the work area 221 for specific control (step S8501). Then, it is determined whether or not the value of the set value counter provided in the work area 221 for specific control is 1 or more corresponding to "setting 1" and 6 or less corresponding to "setting 6" (step S8502). When the value of the set value counter is "0" or is 7 or more, a negative determination is made in step S8502 and "1" is set in the set value counter (step S8503). As a result, the set value of the pachinko machine 10 becomes "setting 1".

When an affirmative determination is made in step S8502 or the processing of step S8503 is executed, it is determined whether or not the reset button 68c has been pressed (step S8504). When the reset button 68c is not pressed (step S8504: NO), the value of the set value counter in the work area 221 for specific control is set on condition that the update button 68b is pressed (step S8505: YES). Is incremented by 1 (step S8506). As a result, each time the update button 68b is pressed once, the set value is updated by one step. If the update button 68b is not pressed (step S8505: NO) or if the value of the set value counter is incremented by 1, the process returns to step S8502. If it is determined that the value is 7 or more, "1" is set in the set value counter in step S8503. As a result, when the update button 68b is pressed once in the situation of "setting 6", the process returns to "setting 1".

When the reset button 68c is pressed (step S8504: YES), the current set value is confirmed and the process proceeds to step S8507. In step S8507, it is determined whether the setting key insertion unit 68a has been turned off using the setting key. In this case, it may be configured to determine whether the setting key inserting section 68a is switched from the ON state to the OFF state, or may be configured to determine whether the setting key inserting section 68a is in the OFF state. If the setting key insertion unit 68a has not been turned off (step S8507: NO), the process of step S8507 is executed again.

When the setting key insertion unit 68a is turned off (step S8507: YES), the setting update display flag in the specific control work area 221 is cleared to "0" (step S8508).

According to the above configuration, in the configuration in which the set value is updated by pressing the update button 68b, the set value is confirmed by pressing the reset button 68c, and the setting key insertion section 68a is turned off. As a result, the setting value update process is completed. That is, in order to end the setting value updating process after updating the setting value in the setting value updating process, it is necessary to press the reset button 68c in addition to turning off the setting key insertion portion 68a. As a result, it becomes possible to make it difficult to carry out an act of playing a game with the set value after the set value is illegally updated.

<35th Embodiment>
In this embodiment, the processing configuration relating to display control of the first to fourth notification display devices 201 to 204 executed by the main CPU 63 is different from that in the 33rd embodiment. The configuration different from that of the 33rd embodiment will be described below. The description of the same configuration as the thirty-third embodiment is basically omitted.

FIG. 126 is an explanatory diagram for explaining the electrical configuration of the calculation result storage area 234 provided in the work area 223 for non-specific control.

The calculation result storage area 234 stores information on the base value calculated by the main CPU 63. The base value is for the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) in a situation where neither the open/close execution mode due to the big hit result nor the high frequency support mode is present. It is the ratio of the total payout number of game balls.

In detail regarding the calculation of the base value, although the normal counter area 231 is provided in the work area 223 for non-specific control in the present embodiment, the open/close execution mode counter area 232 and the high frequency support mode counter area 233 are provided. Is not provided. Similar to the fifteenth embodiment, the normal counter area 231 has a normal general prize winning counter 231a, a normal special electric prize winning counter 231b, a normal first operating counter 231c, a normal second operating counter 231d and A normal out counter 231e is provided. In a situation where neither the open/close execution mode due to the big hit result nor the high frequency support mode is present, when one game ball enters the general winning opening 31, the value of the normal general winning counter 231a is incremented by 1, When one game ball enters the prize winning device 32, the value of the special electric prize winning counter 231b for normal is incremented by 1, and when one game ball enters the first operating port 33, it is for normal use. The value of the first operation counter 231c of 1 is added, and when one game ball enters the second operation port 34, the value of the normal second operation counter 231d is added by 1, and the value is added to the outlet 24a. When one game ball enters, the value of the normal out counter 231e is incremented by 1. Then, when the values of the various counters 231a to 231e of the normal counter area 231 are K91 to K95 in a situation where neither the open/close execution mode based on the jackpot result nor the high frequency support mode is used, the base values are as follows.
Base value: total payout number of game balls (K91 x "number of prize balls for winning in general prize hole 31" + K92 x "number of prize balls for winning in special electric prize winning device 32" + K93 x "to first operating port 33" Ratio of the total number of game balls discharged from the game area PA (K91+K92+K93+K94+K95)+K94דnumber of prize balls for winning in the second operation port 34”)/K94.

The calculation of the base value is performed every time the result calculation process (FIG. 130) described later is executed in the management process (step S8920) of the first timer interrupt process (FIG. 133) described below, but the normal counter area The values of the various counters 231a to 231e of H.231 are in a situation where "1" is not set in the management start flag provided in the work area 223 for non-specific control, and the opening/closing execution mode and the high-frequency support mode depend on the jackpot result. When the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) becomes the management start reference number in a situation that is neither of the above, “0” is cleared, The total number of game balls discharged from the game area PA in a situation where the management start flag is set to "1" and is neither the open/close execution mode due to the jackpot result nor the high frequency support mode (that is, the game area PA "0" is cleared when the total number of game balls supplied to (1) becomes the shift reference number.

The management start reference number is set to 300, which is smaller than the shift reference number, as in the fifteenth embodiment. At the shipping stage of the pachinko machine 10 or the like, the operation check of the pachinko machine 10 may be performed before shipping, in which case the game ball is cared for in each ball entry portion and the subsequent operation is checked. The base value in such a situation can be a value different from the situation in which a normal game is played. Therefore, the total number of game balls discharged from the game area PA in a situation where the management start flag is not set to "1" and is neither the open/close execution mode due to the big hit result nor the high frequency support mode (that is, the game) When the total number of game balls supplied to the area PA becomes the management start reference number, which is smaller than the shift reference number, the various counters 231a to 231e in the normal counter area 231 are temporarily cleared to "0". As a result, it is possible to reduce the influence of the above-described operation check on the base value in a situation where a normal game is played after the pachinko machine 10 is shipped. Note that the management start reference number is not limited to 300, and may be any number as long as it is a plurality, and may be set to a number less than 300 or more than 300. Good.

The shift reference number is set to 60,000. In the pachinko machine 10, a maximum of 100 game balls are fired per minute, so 60000 is the maximum number of shots in 10 hours. In this case, the general business hours in the game hall are about 13 hours, and the time during which the game is played is about 10 hours in the situation where neither the open/close execution mode nor the high-frequency support mode depending on the jackpot result. Therefore, the shift reference number is set on the assumption of the maximum number of game balls to be shot in about one business day. By clearing the various counters 231a to 231e in the normal counter area 231 to "0" each time the shift reference number is reached, the base value can be calculated within the range of the shift reference number. Note that the shift reference number is not limited to 60,000, and may be any number as long as it is a plurality, and may be set to a number less than 60,000 or more than 60,000. Good.

The calculation result storage area 234 is provided with a current area 311, a first history area 312, a second history area 313, and a third history area 314 as storage areas for storing the information of the base value. There is. All of these various areas 311 to 314 have the same storage capacity, and specifically, have a capacity of 1 byte so that the information of the base value can be stored.

The current value area 311 stores the base value calculated in the latest result calculation processing (FIG. 130). That is, the latest base value is stored in the current area 311.

In the first history area 312, the final base value in the previous calculation period is stored. In this case, if the previous calculation period is after the management start flag is set to “1”, the first history area 312 has the opening/closing execution mode based on the jackpot result in the previous calculation period. And, the base value at the timing when the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) becomes the shift reference number in a situation that is neither in the high frequency support mode Is stored. Further, if the management start flag is set to “1” after the previous calculation period has elapsed, the first history area 312 displays the opening/closing execution mode based on the jackpot result in the previous calculation period and The base value at the timing when the total number of game balls ejected from the game area PA (that is, the total number of game balls supplied to the game area PA) becomes the management start reference number in a situation that is neither in the high frequency support mode Is stored.

In the second history area 313, the final base value in the calculation period two times before is stored. In this case, if the calculation period two times before is after the management start flag is set to “1”, the second history area 313 has the opening/closing execution mode based on the jackpot result in the calculation period two times before. In addition, the base value at the timing when the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) becomes the shift reference number in a situation that is neither in the high frequency support mode Is stored. Further, if the management start flag is set to “1” after the calculation period of two times before has elapsed, the second history area 313 shows the opening/closing execution mode according to the jackpot result in the calculation period of two times before and The base value at the timing when the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) becomes the management start reference number in a situation that is neither in the high frequency support mode Is stored.

The final base value in the calculation period three times before is stored in the third history area 314. In this case, if the calculation period before three times is after the management start flag is set to "1", the opening/closing execution mode based on the jackpot result in the calculation period before three times is set in the third history area 314. And, the base value at the timing when the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) becomes the shift reference number in a situation that is neither in the high frequency support mode Is stored. If the management start flag is set to “1” after the calculation period three times before has elapsed, the third history area 314 shows the opening/closing execution mode based on the jackpot result in the calculation period three times before and The base value at the timing when the total number of game balls ejected from the game area PA (that is, the total number of game balls supplied to the game area PA) becomes the management start reference number in a situation that is neither in the high frequency support mode Is stored.

The base values stored in the current area 311, the first history area 312, the second history area 313, and the third history area 314 are sequentially reported on the first to fourth notification display devices 201 to 204. Specifically, every time the display continuation period (specifically, 5 seconds) elapses, a current order area 311→first history area 312→second history area 313→third history area 314 is set in a predetermined order. The base value to be notified is switched, and the base value to be notified is switched in the predetermined order.

127(a) to 127(d) are for the first to fourth notifications when the base values stored in the various areas 311 to 314 are notified in the situation where the management start flag is set to "1". 6 is an explanatory diagram for explaining display contents of display devices 201 to 204. FIG. 127(a) shows an example of the display contents of the first to fourth notification display devices 201-204 when the base value stored in the current area 311 is notified, and FIG. 127(b) shows the first history. FIG. 127C shows an example of the display contents of the first to fourth notification display devices 201 to 204 when the base value stored in the area 312 is notified, and FIG. 127C shows the base stored in the second history area 313. FIG. 127D shows an example of display contents of the first to fourth notification display devices 201 to 204 when the value is notified, and FIG. 127D shows the case where the base value stored in the third history area 314 is notified. An example of the display content of the 1st-4th notification display devices 201-204 is shown.

As shown in FIGS. 127(a) to 127(d), each of the first to fourth notification display devices 201 to 204 has eight display segments 321 to 324. Of the eight display segments 321-324, the seven display segments 321-324 are all rod-shaped light emitting regions having the same shape and size, and are arranged so as to generate a "8" shape. Has been done. On the other hand, one display segment 321 to 324 is a circular light emitting region and is located at the lower right position with respect to the seven display segments 321 to 324 arranged in the shape of "8". It is provided. Regardless of which base value of each of the various areas 311 to 314 is notified, at least one display segment 321 to 324 in each of the first to fourth notification display devices 201 to 204 is in a light emitting state.

On the first notification display device 201, a display indicating that the base values are notified on the first to fourth notification display devices 201 to 204 is displayed. Specifically, the character "b" is displayed on the first notification display device 201 regardless of which of the base values in the various areas 311 to 314 is notified. When the information other than the base value is notified on the first to fourth notification display devices 201 to 204, the character “b” is not displayed on the first notification display device 201. Thereby, by confirming that the character "b" is displayed on the first notification display device 201, the manager of the game hall can use the first to fourth notification display devices 201 to 204 as a base. It becomes possible to grasp that the value is notified.

On the second notification display device 202, a display indicating which of the various areas 311 to 314 is being notified of is displayed. Specifically, in a situation where the base value of the current area 311 has been notified, the character “L.” is displayed on the second notification display device 202 as shown in FIG. 127(a). In a situation where the base value of the first history area 312 has been notified, the character “1.” is displayed on the second notification display device 202 as shown in FIG. 127(b). In a situation where the base value of the second history area 313 has been notified, the character “2.” is displayed on the second notification display device 202 as shown in FIG. 127(c). In a situation where the base value of the third history area 314 has been notified, the character “3.” is displayed on the second notification display device 202 as shown in FIG. 127(d). Thus, by checking the characters displayed on the second notification display device 202, the manager of the game hall can determine which base value is notified on the first to fourth notification display devices 201 to 204. It is possible to grasp whether or not it is during the calculation period of.

In the second notification display device 202, the circular display segments 321 to 324 are in a light emitting state even when any of the base values of the various areas 311 to 314 is notified. As will be described later, on the third notification display device 203 and the fourth notification display device 204, any number from "0" to "9" is displayed as a display corresponding to the base value. In this case, when any of the numbers “1” to “3” is displayed on the second notification display device 202, the three numbers are displayed on the second to fourth notification display devices 202 to 204. It will be lined up, and it will be difficult to grasp the base value. On the other hand, when the circular display segments 321 to 324 provided in the lower right of the second notification display device 202 are in the light emitting state, “1” to “” are displayed on the second notification display device 202. Even when any number of "3" is displayed, the number displayed on the second notification display device 202 and the third notification display device 203 and the fourth notification display device 204 are displayed. It is possible to distinguish it from numbers.

On the third notification display device 203 and the fourth notification display device 204, the number of the base value that is the notification target is displayed. Although the base value will be calculated as a decimal number up to the second decimal place, the first decimal place of the base value is displayed on the third notification display device 203, and the decimal place of the base value is displayed. The second digit is displayed on the fourth notification display device 204. Here, when the base value is "1.00", the number "0" is displayed on each of the third notification display device 203 and the fourth notification display device 204. On the other hand, when the base value is not yet stored in the notification target areas 311 to 314, the third notification display device 203 and the fourth notification display are displayed as shown in the explanatory view of FIG. The character "-" is displayed on each of the devices 204. As a result, even when the base value calculated as the decimal point to the second decimal place is notified on the two display devices of the third notification display device 203 and the fourth notification display device 204, the base value It is possible to distinguish the display content from the case where is "1.00" and the case where the base value is not yet stored in the areas 311 to 314 to be notified.

The display contents of the combination of the third notification display device 203 and the fourth notification display device 204 are the same when the base value is “1.00” and when the base value is “0.00”. On the other hand, in order to distinguish between the two, the light emitting state of "00" may be maintained in one of the former and the latter, and the display of "00" may be in a blinking state in the other.

Next, referring to the time chart of FIG. 129, in a situation where the management start flag is set to “1”, the base values of the various areas 311 to 314 are notified on the first to fourth notification display devices 201 to 204. The situation will be described. FIG. 129(a) shows a period in which the base value stored in the current area 311 is notified by the first to fourth notification display devices 201-204, and FIG. 129(b) is stored in the first history area 312. FIG. 129(c) shows that the base value stored in the second history area 313 indicates the first to fourth notifications. 129 (d) shows the base value stored in the third history area 314 in the first to fourth notification display devices 201 to 204. FIG. 129(e) shows the period, and the total of the game balls discharged from the game area PA in the situation where neither the opening/closing execution mode by the jackpot result nor the high-frequency support mode has occurred since the base value calculation period was newly started. The period until the number (that is, the total number of game balls supplied to the game area PA) reaches the initial reference number (specifically, 6000) is shown.

At the timing of t1, as shown in FIG. 129(a), notification of the base value stored in the current area 311 is started on the first to fourth notification display devices 201 to 204. At the time of this notification, as shown in FIG. 127(a), a display indicating that the base value is the notification target is displayed on the first notification display device 201, and is stored in the current area 311 on the second notification display device 202. The display indicating that the base value is the notification target is displayed, and the display corresponding to the base value stored in the current area 311 is displayed on the third notification display device 203 and the fourth notification display device 204.

Here, as shown in FIG. 129(e), the calculation initial display is performed from the timing of t1 to the timing of t2. Specifically, since the base value calculation period was newly started, the total number of game balls discharged from the game area PA in a situation where neither the open/close execution mode due to the big hit result nor the high frequency support mode (that is, the game area) During the period until the total number of game balls supplied to the PA reaches the initial reference number (specifically, 6000), the first notification display device 201 and the second notification display device 202 are displayed. Instead of continuing the lighting of the character, the character to be displayed is blinked and displayed as the calculation initial display. Immediately after the start of the calculation period, since there is little information on the game history for calculating the base value, the actual measurement value of the base value may be a value that is largely outside the theoretical value range of the base value. On the other hand, by causing the calculation initial display to be performed immediately after the calculation period is started in this manner, it becomes possible to let the manager of the gaming hall recognize that it is immediately after the calculation period is started. ..

Further, while the third notification display device 203 and the fourth notification display device 204, in which the number corresponding to the base value is displayed in the initial calculation display, continue to turn on the numbers, the first notification display device. Characters to be displayed are displayed blinking on 201 and the second notification display device 202. As a result, it is possible to notify that the calculation period has just started, while preventing the visibility of the base value from decreasing. It should be noted that the present invention is not limited to this, and even in the initial calculation display, blinking display may be performed on at least one of the third notification display device 203 and the fourth notification display device 204. The display may be performed, or the blinking display may be performed on only one of the first notification display device 201 and the second notification display device 202. Further, the initial reference number is not limited to 6000, and may be any number as long as it is a plurality, and may be set to a number less than 6000 or more than 6000. Good.

At the timing of t2, the total number of game balls discharged from the game area PA in a situation where neither the opening/closing execution mode due to the big hit result nor the high-frequency support mode has been reached from the timing of t1 (that is, the number of game balls supplied to the game area PA). When the total number reaches the initial reference number (specifically, 6000), the calculation initial display is ended as shown in FIG. 129(e). As a result, lighting display is started not only on the third notification display device 203 and the fourth notification display device 204 but also on the first notification display device 201 and the second notification display device 202.

After that, when the display continuation period elapses from the timing of t1 at the timing of t3, the notification of the base value stored in the current area 311 is ended as shown in FIG. As shown, notification of the base value stored in the first history area 312 is started. In this case, since the base value stored in the first history area 312 is the final calculation result of the base value in the previous calculation period, the calculation initial display is not performed.

After that, when the display continuation period elapses from the timing of t3 at the timing of t4, the notification of the base value stored in the first history area 312 is ended as shown in FIG. As shown in (), the notification of the base value stored in the second history area 313 is started. In this case, since the base value stored in the second history area 313 is the final calculation result of the base value in the calculation period two times before, the calculation initial display is not performed.

After that, when the display continuation period elapses from the timing of t4 at the timing of t5, the notification of the base value stored in the second history area 313 is finished as shown in FIG. As shown in (), notification of the base value stored in the third history area 314 is started. In this case, since the base value stored in the third history area 314 is the final calculation result of the base value in the calculation period three times before, the calculation initial display is not performed.

After that, when the display continuation period elapses from the timing of t5 at the timing of t6, the notification of the base value stored in the third history area 314 is ended as shown in FIG. As shown in (), notification of the base value stored in the current area 311 is started. In this case, since the base value calculation period is newly started, the total number of game balls discharged from the game area PA in a situation where neither the open/close execution mode due to the jackpot result nor the high-frequency support mode is present (that is, in the game area PA). 129 (e) over the timing of t6 to the timing of t7 in order to notify that it is a period until the total number of game balls supplied) reaches the initial reference number (specifically, 6000). Initial calculation display is performed as shown in FIG.

After that, when the display continuation period elapses from the timing of t6 at the timing of t8, the notification of the base value stored in the current area 311 is finished as shown in FIG. As shown, notification of the base value stored in the first history area 312 is started. In this case, since the base value stored in the first history area 312 is the final calculation result of the base value in the previous calculation period, the calculation initial display is not performed.

Next, a processing configuration for enabling the notification of the base value as described above will be described.

The management process (step S8920) in the first timer interrupt process (FIG. 133) described later is a process corresponding to the non-specific control in step S3803, like the management process (FIG. 70) in the fifteenth embodiment. Read the management execution process program. Then, in this management execution process (FIG. 71), the check process is executed in step S3908 as in the fifteenth embodiment.

In the check process, in the situation where neither the open/close execution mode due to the big hit result nor the high frequency support mode is specified, when the entry of one game ball into the general winning opening 31 is specified, the normal general winning counter 231a When the value is incremented by 1 and the entry of one gaming ball into the special electric prize winning device 32 is specified, the value of the normal special electric prize counter 231b is incremented by 1, and the value of the first working opening 33 is increased by 1. When the entry of the game ball is specified, the value of the normal first operation counter 231c is incremented by 1, and when the entry of one game ball into the second operation port 34 is specified, the normal operation is performed. The value of the second operation counter 231d is incremented by 1, and when the entry of one gaming ball into the out port 24a is specified, the value of the normal out counter 231e is incremented by 1. In the checking process, the result calculation process and the display process are executed.

FIG. 130 is a flowchart showing the result calculation process. The processes of steps S8601 to S8615 in the result calculation process are executed using the non-specific control program and the non-specific control data in the main CPU 63.

First, a base value calculation process is executed (step S8601). In the calculation process, the base value is calculated using the values of the various counters 231a to 231e in the normal counter area 231. The method of calculating the base value is as described above. Then, the calculated base value is overwritten in the current area 311 (step S8602).

After that, it is determined whether the management start flag provided in the work area 223 for non-specific control is set to "1" (step S8603). The management start flag has a value of “0” when the supply of operating power to the pachinko machine 10 is started for the first time after the pachinko machine 10 is manufactured. Further, when the work area 223 for non-specific control is also initialized by clearing "0" including the management start flag, the value of the management start flag becomes "0". The total number of game balls discharged from the game area PA in a situation where the management start flag is a value of "0" and is neither the open/close execution mode due to the jackpot result nor the high frequency support mode (that is, in the game area PA Since the total number of supplied game balls) becomes the management start reference number, "1" is set in the management start flag. Further, when the management start flag is set to "1", the values of the various counters 231a to 231e in the normal counter area 231 are cleared to "0" and a new calculation period is started. As a result, the influence of the operation check at the shipping stage of the pachinko machine 10 can be made difficult to reach the base value in the situation where a normal game is played after the pachinko machine 10 is shipped.

When a negative determination is made in step S8603, the total number is calculated by summing all the values of the various counters 231a to 231e in the normal counter area 231 (step S8604). Then, it is determined whether or not the calculated total number is greater than the management start reference number of 300 (step S8605).

When a positive determination is made in step S8605, the management start flag is set to "1" (step S8606). After that, a data shift process is executed (step S8607). In the data shift process, the information stored in the current state area 311, the first history area 312, the second history area 313, and the third history area 314 in the calculation result storage area 234 is changed from the second history area 313 to the third history area 314. , First history area 312→second history area 313, current area 311→first history area 312. As a result, the final base value in the calculation period two times before is stored in the third history area 314 as the final base value in the calculation period three times before, and the final base value in the calculation period one time before. Is stored in the second history area 313 as the final base value in the calculation period two times before, and the last calculated base value in the current calculation period is calculated as the final base value in the calculation period one time before. One history area 312 is stored. In the data shift processing, the LDIR instruction is used when the above information shift is performed. In the LDIR instruction, the information stored in the storage area is shifted (copied) to the storage area by designating the address of the storage area of the information and the address of the storage area of the information. Becomes

However, in the situation where the management start flag is not set to "1", the base value information is not basically stored in the first to third history areas 312 to 314, and therefore, in step S8607, the management is substantially performed. Only the shift of the final base value of the calculation period to the first history area 312 in the situation where the start flag is not set to "1" is performed. After that, all the counters 231a to 231e in the normal counter area 231 are cleared to "0" (step S8608).

If an affirmative decision is made in step S8603, the total number is calculated by summing the values of the various counters 231a to 231e in the normal counter area 231 (step S8609). Then, it is determined whether the calculated total number is larger than the initial reference number of 6000 (step S8610). When a negative determination is made in step S8610, "1" is set to the calculation initial flag provided in the work area 223 for non-specific control (step S8611), and when a positive determination is made in step S8610, The calculation initial flag is cleared to "0" (step S8612). The calculation initial flag is the total number of game balls discharged from the game area PA (that is, the game area) in a situation where the base value calculation period is newly started and the open/close execution mode by the jackpot result is neither the high frequency support mode. This is a flag for the main CPU 63 to specify whether or not the total number of game balls supplied to the PA has reached the initial reference number.

When the process of step S8611 or step S8612 is executed, it is determined whether the total number calculated in step S8609 is the shift reference number of 60000 or more (step S8613). If a positive determination is made in step S8613, data shift processing is executed (step S8614). In the data shift process, the information stored in the current state area 311, the first history area 312, the second history area 313, and the third history area 314 in the calculation result storage area 234 is changed from the second history area 313 to the second history area 313 in the same manner as in step S8607. The third history area 314, the first history area 312→the second history area 313, the current area 311→the first history area 312 are shifted in this order. As a result, the final base value in the calculation period two times before is stored in the third history area 314 as the final base value in the calculation period three times before, and the final base value in the calculation period one time before. Is stored in the second history area 313 as the final base value in the calculation period two times before, and the last calculated base value in the current calculation period is calculated as the final base value in the calculation period one time before. One history area 312 is stored. In the data shift processing, the LDIR instruction is used when the above information shift is performed. In the LDIR instruction, the information stored in the storage area is shifted (copied) to the storage area by designating the address of the storage area of the information and the address of the storage area of the information. Becomes After that, all the counters 231a to 231e in the normal counter area 231 are cleared to "0" (step S8615).

FIG. 131 is a flowchart showing the display process. The processing of steps S8701 to S8714 in the display processing is executed by using the non-specific control program and non-specific control data in the main CPU 63.

First, it is determined whether or not "1" is set in the management start flag provided in the work area 223 for non-specific control (step S8701). When an affirmative determination is made in step S8701, the value of the switching timing counter provided in the work area 223 for non-specific control is decremented by 1 (step S8702). The switching timing counter is a display for first to fourth notification among the base values stored in each of the current state area 311, the first history area 312, the second history area 313, and the third history area 314 of the calculation result storage area 234. This is a counter for the main CPU 63 to specify that it is the timing to switch the base value to be notified in the devices 201 to 204. As described above, every time the display continuation period (specifically, 5 seconds) elapses, notification is made in the predetermined order of the current area 311→first history area 312→second history area 313→third history area 314. The target base value is switched, and the switching of the base value to be informed in the predetermined order is repeated.

When the process of step S8702 is executed, it is determined whether or not the value of the switching timing counter after subtracting 1 is “0”, and thus the base value, which is the current notification target, becomes the notification target. It is determined whether or not the display continuation period has elapsed since (step S8703). If an affirmative decision is made in step S8703, the value of the display target counter provided in the work area 223 for non-specific control is incremented by 1 (step S8704). When the value of the display target counter after adding 1 exceeds the maximum value of "3" (step S8705: YES), the value of the display target counter is cleared to "0" (step S8706).

The display target counter is the first to fourth notification displays among the base values stored in the current state area 311, the first history area 312, the second history area 313, and the third history area 314 in the calculation result storage area 234. This is a counter for the main CPU 63 to specify the base value to be notified in the devices 201 to 204. Specifically, when the value of the display target counter is “0”, the base value stored in the current area 311 becomes the notification target, and when the value of the display target counter is “1”, the first history area When the base value stored in 312 is the notification target and the value of the display target counter is “2”, the base value stored in the second history area 313 is the notification target and the value of the display target counter is “3”. , The base value stored in the third history area 314 becomes the notification target.

When a negative determination is made in step S8705, or when the processing of step S8706 is executed, the switching timing counter of the work area 223 for non-specific control is displayed as a value corresponding to the switching timing of the next notification target (specifically, The value corresponding to 5 seconds) is set (step S8707).

If a negative determination is made in step S8703, or if the processing of step S8707 is executed, the display target setting area 276 provided in the work area 223 for non-specific control corresponds to the base value which is the notification target of this time. Perform the process for setting the display data. Specifically, first, display type data corresponding to the value of the display target counter is set in the display target setting area 276 (step S8708). The display type data includes display data for causing the first notification display device 201 to perform a display indicating that the notification target of the first to fourth notification display devices 201 to 204 is the base value, and the notification target base. A display indicating which of the current area 311, the first history area 312, the second history area 313 and the third history area 314 the value corresponds to in the calculation result storage area 234 is displayed on the second notification display device 202. And display data to be executed.

After that, the base value is read from an area corresponding to the value of the display target counter among the current area 311, the first history area 312, the second history area 313, and the third history area 314 in the calculation result storage area 234, and the read base is read. The calculation result data corresponding to the decimal point first digit and the decimal point second digit in the value are set in the display target setting area 276 (step S8709). The calculation result data includes display data for causing the third notification display device 203 to perform a display corresponding to the first decimal place number in the notification target base value, and the second decimal point number in the notification target base value. And display data for causing the fourth notification display device 204 to perform a display corresponding to.

As described above, the display data including the display type data and the calculation result data is set in the display target setting area 276. By transmitting the display data to the display IC 266 in the second timer interrupt process (FIG. 134) described later, the display corresponding to the display data is performed on the first to fourth notification display devices 201 to 204. ..

Further, the process of step S8709 is executed every time the display process (FIG. 131) is executed regardless of the switching timing of the base value to be notified. As described above, every time the calculation result storage process (FIG. 130) is executed, the base value is calculated using the current value in each of the counters 231a to 231e of the normal counter area 231, and the calculated base value is It is stored in the current state area 311 of the calculation result storage area 234. In this case, the processing of step S8709 for setting the calculation result data in the display target setting area 276 as described above is executed every time the display processing (FIG. 131) is executed regardless of the switching timing of the base value of the notification target. When the base value of the current area 311 is changed in the situation where the base value is changed, the changed base value can be notified.

Then, it is determined whether or not the base value of the current area 311 is the notification target based on the value of the display target counter (step S8710), and the calculation initial flag provided in the work area 223 for non-specific control is set to " It is determined whether "1" is set (step S8711). As already described, the calculation initial flag is the total number of game balls discharged from the game area PA in a situation where the base value calculation period is newly started and the open/close execution mode by the big hit result is neither the high frequency support mode. This is a flag for the main CPU 63 to specify whether or not (that is, the total number of game balls supplied to the game area PA) has reached the initial reference number. If a positive determination is made in both step S8710 and step S8711, "1" is set to the initial display flag provided in the work area 223 for non-specific control (step S8712), and either step S8710 or step S8711 is performed. When the negative determination is made in step S6, the initial display flag is cleared to "0" (step S8713).

The initial display flag is used for the first notification display device 201 to notify that the base value is the initial calculation base value after the start of the calculation period in the situation where the base value of the current area 311 is the notification target. And a flag for the main CPU 63 to specify that the second notification display device 202 should be displayed in a blinking manner. When it is specified that the initial display flag is set to “1” in the second timer interrupt process (FIG. 134) described later, the display data stored in the display target setting area 276 is simply transmitted to the display IC 266. When the first to fourth notification display devices 201 to 204 are caused to perform the display corresponding to the display data, the first notification display device 201 and the second notification display device 202 are blinked and the third The notification display device 203 and the fourth notification display device 204 are lit and displayed. When it is specified that the initial display flag is not set to "1" in the second timer interrupt process (FIG. 134) described later, the display corresponding to the display data stored in the display target setting area 276 is displayed first. When the first to fourth notification display devices 201 to 204 are used, all of the first to fourth notification display devices 201 to 204 are lit and displayed.

On the other hand, if "1" is not set in the management start flag provided in the work area 223 for non-specific control and a negative determination is made in step S8701, the current area 311 is read regardless of the value of the display target counter. The base value is read, and the calculation result data corresponding to the first decimal place number and the second decimal place number in the read base value are set in the display target setting area 276 (step S8714). By transmitting the display data corresponding to the calculation result data to the display IC 266, the first decimal place number in the base value of the current area 311 is displayed on the third notification display device 203, and the base of the current area 311 is displayed. The second digit of the decimal point in the value is displayed on the fourth annunciator display device 204. With the above configuration, when the management start flag is not set to "1", the base value in the past calculation period is not notified, and only the base value calculated in the current calculation period is notified. To be done.

When the management start flag is not set to "1", the calculation result data is set in the display target setting area 276, but the display type data is not set. Although details will be described later, when the base value is notified in a situation where “1” is not set in the management start flag, the display contents of the first notification display device 201 and the second notification display device 202 are managed. The display content is different from that when the base value is notified in the situation where the start flag is set to "1".

Next, the main processing in this embodiment executed by the main CPU 63 will be described with reference to the flowchart in FIG. The processes of steps S8801 to S8825 in the main process are executed by using the program for specific control and the data for specific control in the main CPU 63.

First, power-on initialization processing is executed (step S8801). In the power-on initialization process, for example, a predetermined wait time (specifically, 1 second) elapses after the main process is started, and the process waits without proceeding to the next process. In the predetermined period for this weight, the operation start and initial setting of the symbol display device 41 are completed. Also, access to the main RAM 65 is permitted.

After that, an internal function register setting process is executed (step S8802). In the internal function register setting process, the interrupt period of the first timer interrupt process (FIG. 133), which is a process that is periodically interrupted and activated with respect to the main process, is the first interrupt period (specifically, 4 milliseconds). And the interrupt period of the second timer interrupt process (FIG. 134), which is a process that is activated by periodically interrupting the main process, is set to a second interrupt period that is shorter than the first interrupt period. (Specifically, it is set to 2 milliseconds).

That is, in the present embodiment, similar to the 33rd embodiment, the timer interrupt processing includes the first timer interrupt processing and the second timer interrupt processing so that the interrupt cycle becomes relatively long and short. Both the first timer interrupt process and the second timer interrupt process are activated by interrupting the main process. Further, the second timer interrupt process is activated by interrupting the first timer interrupt process. On the other hand, the first timer interrupt process does not start by interrupting the second timer interrupt process. If both the first interrupt cycle and the second interrupt cycle have passed in a situation where neither the first timer interrupt process nor the second timer interrupt process is being executed, the second The timer interrupt processing is started first. In this respect, it can be said that the second timer interrupt process is a process activated prior to the first timer interrupt process. However, the configuration is not limited to this, and the first timer interrupt process may be activated prior to the second timer interrupt process.

In the internal function register setting process, the first interrupt cycle of the first timer interrupt process is set in a predetermined register of the main CPU 63, and the second interrupt cycle of the second timer interrupt process is set in a specific register of the main CPU 63. To do. Further, in the internal function register setting process, in addition to the setting of the first and second interrupt cycles, the setting process of the numerical range of various counters such as the numerical range of the hit random number counter C1 is executed.

After that, "1" is set to the startup processing flag provided in the work area 221 for specific control (step S8803). Even if the first timer interrupt processing is activated, the startup processing in progress flag executes the processing for performing power failure monitoring, updating various counters, and illegal monitoring among the various processing set in the first timer interrupt processing. On the other hand, it is a flag for the main CPU 63 to specify that the first timer interrupt process should be ended without executing the process for advancing the game.

FIG. 133 is a flowchart showing the first timer interrupt processing in this embodiment executed by the main CPU 63. It should be noted that the first timer interrupt process is periodically activated at the 4 ms cycle, which is the first interrupt cycle, as already described. Further, the program corresponding to the first timer interrupt processing is set to the program for specific control.

In steps S8901 to S8905, the same processes as steps S301 to S305 of the timer interrupt process (FIG. 11) in the first embodiment are executed. That is, power failure monitoring is performed by executing power failure information storage processing in step S8901. Specifically, similarly to the power failure information storage processing (FIG. 101) in the thirtieth embodiment, it is monitored whether or not a power failure signal corresponding to the occurrence of power shutdown is received from the power failure monitoring board 67, and the power failure is detected. When the occurrence of is specified, it becomes an infinite loop after executing the process at the time of power failure. In the power failure process, "1" is set to the power failure flag provided in the specific control work area 221, a checksum is calculated, and the calculated checksum is stored in the specific control work area 221. In addition, by executing the random number updating process for lottery in step S8902, each numerical value information of the winning random number counter C1, the jackpot type counter C2, the reach random number counter C3, and the general electric utility open counter C4 is updated, and in step S8903. The numerical information of the random number initial value counter CINI is updated by executing the random number initial value updating process, and the numerical information of the fluctuation type counter CS is updated by executing the fluctuation counter updating process in step S8904. Further, by executing the fraud detection processing in step S8905, it is monitored whether or not an event set as a fraudulent monitoring target has occurred. In the fraud detection process, the occurrence of multiple types of events is monitored, and by confirming that any of these multiple types of events has occurred, the game stop provided in the work area 221 for specific control is stopped. Set "1" to the flag.

After executing the processes of steps S8901 to S8905, it is determined whether or not "1" is set to either the game stop flag or the in-progress process flag provided in the work area 221 for specific control. (Step S8906). When "1" is not set to either the game stop flag or the in-progress process flag (step S8906: NO), the processes of step S8907 to step S8920 are executed. In steps S8907 to S8919, the same processes as steps S8208 to S82020 of the first timer interrupt process (FIG. 117) in the thirty-third embodiment are executed. Further, in step S8920, although the management process is executed similarly to step S8221 of the first timer interrupt process (FIG. 117) in the thirty-third embodiment, the contents of the check process of the management execution process called in the management process. Has already been explained. In the check processing, update processing of each of the counters 231a to 231e in the normal counter area 231 is executed, and at the same time, result calculation processing (FIG. 130) and display processing (FIG. 131) are executed.

On the other hand, when "1" is set to at least one of the game stop flag and the startup processing flag (step S8906: YES), the first timer interrupt processing is performed without executing the processing of steps S8907 to S8920. finish. That is, not only when the game stop flag is set to "1" but also when the startup processing flag is set to "1", the processing of steps S8901 to S8905 in the first timer interrupt processing is performed. While executing, the processes of steps S8907 to S8920 are not executed.

As for the start-up processing flag, the processing at the start of supply of operating power (steps S8801 to S8819) is started and the interruption permission (step S8805) is started in the main processing (FIG. 132) as in the 33rd embodiment. "1" is set before the operation is performed, and "0" is cleared before the processing at the start of supplying the operating power is finished and the residual processing (steps S8822 to S8825) is started. In this case, as described above, in the first timer interrupt processing, when the start-up processing flag is set to "1", the processing of steps S8907 to S8920 is not executed, thereby supplying the operating power. It is possible to prevent the process for advancing the game from being executed in the situation where the process at the start (steps S8801 to S8819) is being executed. On the other hand, as described above, in the first timer interrupt processing, even when the start-up processing flag is set to "1", the processing of steps S8901 to S8905 is executed to start the supply of the operating power. Even when the process (step S8801 to step S8819) is being executed, power failure monitoring is performed, and the winning random number counter C1, the jackpot type counter C2, the reach random number counter C3, and the random number initial value counter CINI are updated. It is executed, and further fraud detection is executed.

In particular, even when the start-up processing flag is set to "1", the power failure information storage processing (step S8901) is executed, so that the operation power supply start processing (steps S8801 to S8819) is started. Even if a power failure occurs in the situation in which (1) is being executed, it is possible to execute the power failure process for it. In the power failure process, as already described, the power failure flag provided in the specific control work area 221 is set to "1", the checksum is calculated, and the calculated checksum is stored in the specific control work area 221. Since the data is saved, it is possible to prevent the occurrence of an abnormality in the main RAM 65 when the supply of operating power is restarted. As a result, even when a power failure occurs during the set value update process (step S8819), the set value selected at that time can be stored and held as the set value of the current pachinko machine 10. .. Therefore, even if a power failure occurs during execution of the set value updating process, it becomes unnecessary to execute the set value updating process again when the supply of operating power is restarted.

By the way, in the situation where the set value updating process is executed, the interrupt is not prohibited in both the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134), and the interrupt is generated at an arbitrary timing. It is possible. In this case, if the first timer interrupt process (FIG. 133) or the second timer interrupt process (FIG. 134) is activated in the main process (FIG. 132) including the setting value update process, the target is to be activated. The information of the return address of the main process (FIG. 132) for returning after the end of the interrupted timer interrupt process is saved in the stack area 222 for specific control, and the main side immediately before the timer interrupt process is activated. Information of various registers of the CPU 63 is saved in the stack area 222 for specific control. Then, when the timer interrupt process that is the activation target ends, the process returns to the process of the main process (FIG. 132) corresponding to the information of the return address saved in the stack area 222 for specific control, and The information saved in the stack area 222 for specific control is restored to various registers of the main CPU 63.

Returning to the explanation of the main processing (FIG. 132 ), after setting the start-up processing flag to “1” in step S8803, the initial check period (specifically, the counter during check in the work area 221 for specific control) A value corresponding to 5 seconds) is set (step S8804). In the present embodiment, when the supply of the operating power to the main CPU 63 is started, can each of the display segments 321 to 324 provided in the first to fourth notification display devices 201 to 204 normally emit light? In order to allow the manager of the gaming hall to confirm whether or not the check display is performed on the first to fourth notification display devices 201 to 204 until the initial check period elapses after the processing in step S8804 is started. .. As the check display, specifically, all the display segments 321 to 324 of the first to fourth notification display devices 201 to 204 are maintained in the light emitting state as shown in the explanatory view of FIG. 128(b). .. In step S8804, information corresponding to this initial check period is set in the checking counter.

The initial check period is required until the process for controlling the progress of the game is started when none of the processes of step S8811, step S8812, step S8815, and step S8819 described later is executed in the main process. It is set longer than the longest time. Therefore, the game may be started in a situation where the check display is being performed on the first to fourth notification display devices 201 to 204.

After that, interrupt permission is set (step S8805). As a result, the first timer interrupt process (FIG. 133) is interrupted and activated in the first interrupt cycle, and the second timer interrupt process (FIG. 134) is interrupted and activated in the second interrupt period. However, since "1" is set in the start-up processing flag in step S8803, even if the first timer interrupt processing is activated, power failure monitoring and various counters of various kinds of processing of the first timer interrupt processing are performed. While the processing for updating and fraud monitoring is executed, the first timer interrupt processing is ended without executing the processing for advancing the game.

After that, in steps S8806 to S8825, the same processes as steps S7905 to S7924 of the main process (FIG. 114) in the thirty-third embodiment are executed. Specifically, in step S8806, it is determined whether the reset button 68c is pressed. That is, it is determined whether or not the power of the pachinko machine 10 is turned on while the reset button 68c is being pressed and the supply of operating power to the main CPU 63 is started. Here, in the present embodiment, similar to the 33rd embodiment, the main control device 60 is provided with the setting key insertion portion 68a and the reset button 68c, but is not provided with the update button 68b. Further, the main control device 60 is provided with not the first to third notification display devices 69a to 69c but the first to fourth notification display devices 201 to 204 as in the eleventh embodiment.

When the reset button 68c is not pressed (step S8806: NO), it is determined whether or not "1" is set in the power failure flag provided in the work area 221 for specific control (step S8807). When the power failure information storage processing (step S8901) of the first timer interrupt processing (FIG. 133) executes the power failure processing, the power failure flag is set to "1". The power outage flag is a flag for the main CPU 63 to specify whether or not the power outage process was appropriately performed at the previous power off time.

When "1" is set in the power failure flag (step S8807: YES), checksums are calculated for the specific control work area 221 and the specific control stack area 222 (step S8808). The method of calculating the checksum is the same as in the 33rd embodiment. After that, the specific control work area 221 and the specific control work area 221 that are calculated and stored in the specific control work area 221 in the power failure process executed immediately before the supply of the operating power to the main CPU 63 is stopped. The checksum for the stack area 222 is read from the work area 221 for specific control, and the read checksum is compared with the checksum calculated in step S8808 (step S8809). Then, it is determined whether the checksums match (step S8810).

When a negative determination is made in step S8807 or step S8810, that is, when the power failure flag is not set to "1" or the checksums do not match, the game stop flag provided in the work area 221 for specific control Is set to "1" (step S8811). When the game stop flag is set to "1", the processes of steps S8901 to S8905 are executed in the first timer interrupt process (FIG. 133), while the positive determination is made in step S8906 to steps S8907 to step. The process of S8920 is not executed. As a result, if the power failure flag is not set to "1" because the power failure process was not properly performed at the previous power shutdown, or the specific control work area 221 and the specific control stack area 222 are set. If the checksums do not match for at least one of the above due to the information storage state changing since the last power-off, the processing for power failure monitoring, updating various counters, and unauthorized monitoring is executed. On the other hand, the processing for advancing the game is not executed.

After that, at the start of supplying the operating power, an abnormality command indicating that an abnormality has occurred with respect to the power failure flag or the checksum is transmitted to the sound emission control device 81 (step S8812). Upon receiving the abnormal command, the sound emission control device 81 causes the display light emitting unit 53 to emit light in a manner corresponding to the information abnormality at the time of starting the supply of the operating power, and the speaker unit 54 "Please change the setting." Is output. Moreover, the character image "Please change the setting." is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are ended when the supply of operating power to the pachinko machine 10 is stopped. However, even if the supply of the operating power to the pachinko machine 10 is temporarily stopped, the above notification is given when the supply of the operating power to the pachinko machine 10 is restarted until the setting value updating process (step S8819) is executed. It may be configured to continue.

When the power failure flag is set to "1" and the checksum is normal (step S8807 and step S8810: YES), it is determined whether the setting key insertion unit 68a is turned on by using the setting key. Then (step S8813), it is determined whether or not the front door frame 14 is open with respect to the inner frame 13 and the gaming machine body 12 is open with respect to the outer frame 11 (step S8814). The front door opening sensor 95 is used to detect whether or not the front door frame 14 is opened with respect to the inner frame 13 as in the thirtieth embodiment, and the gaming machine main body 12 is detected with respect to the outer frame 11. The main body open sensor 96 is used to detect whether or not it is in the open state, as in the thirtieth embodiment. The setting key insertion portion 68a is turned on by using the setting key (step S8813: YES), the front door frame 14 is open from the inner frame 13, and the gaming machine body is opened from the outer frame 11. If 12 is in the open state (step S8814: YES), the setting confirmation process is executed (step S8815). The details of the setting confirmation process will be described later.

When the reset button 68c is pressed (step S8806: YES), RAM clear processing is executed (step S8816). The contents of the RAM clear process are the same as step S7915 of the main process (FIG. 114) in the 33rd embodiment. After that, the setting key insertion unit 68a is turned on by using the setting key (step S8817: YES), and the front door frame 14 is open to the inner frame 13 and the outer frame 11 is played. When the machine body 12 is in the open state (step S8818: YES), the set value updating process is executed (step S8819). Details of the setting value update processing will be described later.

When the process of step S8812 is performed, when the negative determination is made at step S8813 or step S8814, when the process of step S8815 is performed, when the negative determination is made at step S8817 or step S8818, or the process of step S8819 is performed. If executed, the start-up processing flag in the specific control work area 221 is cleared to "0" (step S8820). By clearing the start-up processing flag "0", the state in which the processing for advancing the game is not executed even if the first timer interrupt processing is started is released. In step S8820, the power failure flag in the specific control work area 221 is also cleared to "0".

After that, a return command is transmitted to the voice emission control device 81 (step S8821). The content of the information included in the return command and the processing content of the voice emission control device 81 when the return command is received are the same as those in step S7920 of the main processing (FIG. 114) in the 33rd embodiment. ..

After that, the process proceeds to the residual process of steps S8822 to S8825. In other words, the main CPU 63 is configured to periodically execute the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134), but between the one timer interrupt process and the next timer interrupt process. There will be some residual time. This remaining time will vary depending on the processing completion time of each timer interrupt processing, but the remaining processing of steps S8822 to S8825 is repeatedly executed using this irregular time. In this respect, it can be said that the residual process of steps S8822 to S8825 is an irregular process that is irregularly executed. In steps S8822 to S8825, the same processing as steps S113 to S116 of the main processing (FIG. 9) in the first embodiment is executed.

Next, the second timer interrupt processing in this embodiment executed by the main CPU 63 will be described with reference to the flowchart of FIG. The processes of steps S9001 to S9014 in the second timer interrupt process are executed by the main CPU 63 using the specific control program and the specific control data.

First, in order to prohibit the occurrence of the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134), interrupt prohibition is set (step S9001). Since the generation of the first timer interrupt process (FIG. 133) is prohibited, the first timer interrupt process (FIG. 133) interrupts the second timer interrupt process (FIG. 134) even if the first interrupt cycle has elapsed. It is possible to prevent it from being started with. Further, since the generation of the second timer interrupt process (FIG. 134) is prohibited, even if the second interrupt period elapses during the execution of the second timer interrupt process (FIG. 134), the second timer interrupt process is performed. It is possible to prevent the processing (FIG. 134) from being activated in duplicate.

After that, update processing of the checking counter is executed (step S9002). In the updating process of the checking counter, when the value of the checking counter provided in the work area 221 for specific control is 1 or more, the value of the checking counter is decremented by 1. As a result, when the initial check period is being measured using the checking counter, the value of the checking counter is periodically subtracted every time the second timer interrupt process (FIG. 134) is started. The Rukoto.

After that, it is determined whether the setting update display flag in the specific control work area 221 is set to "1" (step S9003). The setting update display flag is a flag for the main CPU 63 to specify whether or not the setting value update processing (FIG. 137) is being executed by the main CPU 63. As described above, the set value updating process (FIG. 137) is performed in the situation where the process at the start of the supply of the operating power is executed in the main process (FIG. 132) when the supply of the operating power to the main CPU 63 is started. Although it will be executed, the second timer interrupt process (FIG. 134) is started by interrupting even when the process at the start of supply of the operating power is being executed. Even in the situation where the value update process (FIG. 137) is being executed, the second timer interrupt process (FIG. 134) is interrupted and activated.

The situation where the setting update display flag is set to "1" means that the main CPU 63 is executing the setting value update processing (FIG. 137) this time of the second timer interrupt processing (FIG. 134). It means that the process is started by interrupting the situation. If an affirmative decision is made in step S9003, a setting process for the fifth display data buffer 275 during the setting update is executed (step S9004). In the setting process, similar to step S8403 of the second timer interrupt process (FIG. 123) in the thirty-third embodiment, the setting values of the pachinko machine 10 are updated on the first to fourth notification display devices 201 to 204. The fifth display data buffer 275 stores the display data for displaying the current status and the current setting value of the pachinko machine 10. As a result, similar to the 33rd embodiment, on the first to fourth notification display devices 201 to 204, a display indicating that the setting value is being updated and a display indicating the current setting value. Is done.

When a negative determination is made in step S9003, it is determined whether the setting confirmation display flag in the specific control work area 221 is set to "1" (step S9005). The setting confirmation display flag is a flag for the main CPU 63 to specify whether or not the setting confirmation processing (FIG. 136) is being executed by the main CPU 63. As described above, the setting confirmation process (FIG. 136) is performed in the main process (FIG. 132) when the supply of the operating power to the main CPU 63 is started and the process at the start of the supply of the operating power is executed. Although it will be executed, the second timer interrupt process (FIG. 134) is started by interrupting even when the process at the start of supply of the operating power is being executed. Even in the situation where the confirmation process (FIG. 136) is being executed, the second timer interrupt process (FIG. 134) is interrupted and activated.

The situation in which the setting confirmation display flag is set to "1" means that the main CPU 63 is executing the setting confirmation processing (FIG. 137) for the current processing time of the second timer interrupt processing (FIG. 134). It means that the process is started by interrupting the situation. When an affirmative determination is made in step S9005, the setting processing for the fifth display data buffer 275 during the setting confirmation is executed (step S9006). In the setting process, similarly to step S8405 of the second timer interrupt process (FIG. 123) in the thirty-third embodiment, the set values of the pachinko machine 10 are confirmed on the first to fourth notification display devices 201 to 204. The fifth display data buffer 275 stores the display data for displaying the current status and the current setting value of the pachinko machine 10. As a result, similar to the 33rd embodiment described above, a display indicating that the setting value is being confirmed and a display indicating the current setting value on the first to fourth notification display devices 201 to 204. Is done.

When a negative determination is made in step S9005, normal setting processing is executed (step S9007). The normal setting process will be described later in detail.

When the process of step S9004, step S9006 or step S9007 is executed, the process of steps S9008 to S9014 is executed. The processing contents of these steps S9008 to S9014 are the same as the steps S8407 to S8413 of the second timer interrupt processing (FIG. 123) in the thirty-third embodiment.

Specifically, first, the transmission state of the signal through the type data signal line LN1 and the type clock signal line LN2 is set to the OFF state (step S9008), and the signal is transmitted through the display data signal line LN3 and the display clock signal line LN4. The state is turned off (step S9009). After that, the update processing of the type counter provided in the work area 221 for specific control is executed (step S9010).

The type counter is a counter for the main CPU 63 to specify the transmission target of display data among the first to fifth display data buffers 271 to 275 in the current processing time of the second timer interrupt processing. When the value of the type counter is "1", the display data of the first display data buffer 271 is the transmission target, and when the value of the type counter is "2", the display data of the second display data buffer 272 is the transmission target. When the value of the type counter is “3”, the display data of the third display data buffer 273 is the transmission target, and when the value of the type counter is “4”, the display data of the fourth display data buffer 274 is When it becomes a transmission target and the value of the type counter is “5”, the display data of the fifth display data buffer 275 becomes a transmission target. In the type counter update process, the value of the type counter is incremented by 1, and if the value of the type counter after adding 1 exceeds the upper limit value of "5", the value of the type counter is set to "1". .. As a result, the transmission target of display data is sequentially changed in the first to fifth display data buffers 271 to 275 for each processing time of the second timer interrupt processing.

After that, the type data corresponding to the value of the type counter is read from the main ROM 64 (step S9011). Specifically, when the value of the type counter is "1", the type data corresponding to the first display circuit 261 is read from the main ROM 64, and when the value of the type counter is "2", the second type data is read. The type data corresponding to the display circuit 262 is read from the main ROM 64, and when the type counter value is “3”, the type data corresponding to the third display circuit 263 is read from the main ROM 64 and the type counter value is When it is "4", the type data corresponding to the fourth display circuit 264 is read from the main ROM 64, and when the type counter value is "5", the type data corresponding to the fifth display circuit 265 is mainly read. Read from the side ROM 64.

After that, the display data is read from the display data buffers 271-275 corresponding to the value of the type counter (step S9012). Specifically, when the value of the type counter is "1", the display data is read from the first display data buffer 271, and when the value of the type counter is "2", the second display data buffer 272 is read. When the display data is read and the value of the type counter is “3”, the display data is read from the third display data buffer 273, and when the value of the type counter is “4”, the fourth display data buffer 274 is read. The display data is read, and when the value of the type counter is "5", the display data is read from the fifth display data buffer 275.

After that, transmission processing of various signals is executed (step S9013). In the transmission processing, signals are output to the type data signal line LN1 and the type clock signal line LN2 so that the type data read in step S9011 is transmitted to the display IC 266. Further, in the transmission process, signals are output to the display data signal line LN3 and the display clock signal line LN4 so that the display data read in step S9012 is transmitted to the display IC 266.

After that, interrupt permission is set to permit the generation of the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134) (step S9014).

FIG. 135 is a flowchart showing the normal setting processing in step S9007 of the second timer interrupt processing (FIG. 134). The processes of steps S9101 to S9109 in the normal setting process are executed by the main CPU 63 using the specific control program and the specific control data.

First, it is determined whether the value of the checking counter provided in the specific control work area 221 is 1 or more (step S9101). When the value of the checking counter is 1 or more (step S9101: YES), it means that it is the initial check period. In this case, the check display data is set in the fifth display data buffer 275 in the specific control work area 221 (step S9102). The display data set in the fifth display data buffer 275 is display data for controlling the display of the first to fourth notification display devices 201 to 204 as described above. In addition, the check display data is display data for causing the first to fourth notification display devices 201 to 204 to perform the check display, that is, the first to fourth notification display devices 201 to 204, respectively. This is display data for putting all the display segments 321 to 324 into a light emitting state. By supplying the data for the check display to the display IC 266, as shown in the explanatory view of FIG. 128(b), all of the first to fourth notification display devices 201 to 204 are used as the check display. The display segments 321 to 324 are in a light emitting state. Thereby, the manager of the game hall can grasp whether or not each of the display segments 321 to 324 of the first to fourth notification display devices 201 to 204 can normally be in the light emitting state.

Here, the initial check period can be canceled when confirming the setting or updating the set value. The cancelable configuration will be described. FIG. 136 is a flowchart showing the setting confirmation process executed in step S8815 of the main process (FIG. 132). The processes of steps S9201 to S9206 in the setting confirmation process are executed by using the specific control program and the specific control data in the main CPU 63.

First, the operation instruction command is transmitted to the voice emission control device 81 (step S9201). Upon receiving the operation instruction command, the voice emission control device 81 causes the speaker 54 to output a voice "Please operate the reset button 68c." The notification is continued until the reset button 68c is pressed.

Then, it is determined whether or not the reset button 68c has been pressed (step S9202). If the reset button 68c has not been pressed, the process waits in step S9202. When the reset button 68c is pressed (step S9202: YES), the checking counter provided in the specific control work area 221 is cleared to "0" (step S9203). This cancels the initial check period.

After that, "1" is set to the setting confirmation display flag provided in the work area 221 for specific control (step S9204). When the setting confirmation display flag is set to "1", the second timer interrupt process (FIG. 134) makes a positive determination in step S9005 as described above, and the first to fourth notification display devices 201 to 201 In the fifth display data buffer 275, display data is stored in the fifth display data buffer 275 for displaying that the setting value of the pachinko machine 10 is being confirmed at 204 and the current setting value of the pachinko machine 10 is being displayed. (Step S9006). As a result, similar to the 33rd embodiment described above, a display indicating that the setting value is being confirmed and a display indicating the current setting value on the first to fourth notification display devices 201 to 204. Is done.

Then, on condition that the setting key insertion unit 68a is turned off (step S9205: YES), the setting confirmation display flag in the specific control work area 221 is cleared to "0" (step S9206). Accordingly, on the first to fourth notification display devices 201 to 204, a display indicating that the current set value of the pachinko machine 10 is being confirmed and a display indicating the current set value of the pachinko machine 10 are displayed. The state in which is performed is released. In this case, the display indicating the base value is started on the first to fourth notification display devices 201 to 204.

When the setting confirmation process is started as described above, on condition that the reset button 68c is pressed, the initial check period is canceled halfway and the first to fourth notification display devices 201 to 204 are used. The set value of is notified. As a result, when the supply of the operating power to the main CPU 63 is started and the main processing (FIG. 132) is started in the main CPU 63, the processing at the start of the supply of the operating power in the main processing is executed. Even if the initial check period is started and the check display is performed on the first to fourth notification display devices 201 to 204 in such a situation, the process at the start of the supply of the operating power is executed. In the case where the set value is confirmed under the above situation, it is possible to cancel the initial check period and display the present set value on the first to fourth notification display devices 201 to 204. Therefore, the set value can be confirmed without waiting for the initial check period to elapse.

Further, even when the setting confirmation process (FIG. 136) is executed in the main process (FIG. 132), the initial check period is started first, so that the first to fourth notification display devices 201 to 204 are not displayed. It is possible to confirm the set value after confirming whether or not each display segment 321 to 324 in each of them can normally emit light. This makes it possible to accurately confirm the set value.

FIG. 137 is a flowchart showing the setting value update processing executed in step S8819 of the main processing (FIG. 132). Note that the processing of steps S9301 to S9310 in the setting value update processing is executed using the program for specific control and the data for specific control in the main CPU 63.

First, an update start command is transmitted to the voice emission control device 81 (step S9301). Upon receiving the update start command, the voice emission control device 81 causes the speaker unit 54 to output the voice "settings are being changed." The notification is continued until the setting value updating process is completed.

Then, it is determined whether or not the value of the set value counter provided in the work area 221 for specific control is 1 or more corresponding to "setting 1" and 6 or less corresponding to "setting 6" (step S9302). When the value of the set value counter is "0" or is 7 or more, a negative determination is made in step S9302 and "1" is set in the set value counter (step S9303). As a result, the set value of the pachinko machine 10 becomes "setting 1".

If an affirmative decision is made in step S9302 or if the processing of step S9303 is executed, it is decided whether or not the setting key insertion portion 68a has been turned OFF using the setting key (step S9304). In this case, it may be configured to determine whether the setting key inserting section 68a is switched from the ON state to the OFF state, or may be configured to determine whether the setting key inserting section 68a is in the OFF state.

If the setting key insertion unit 68a has not been operated to OFF (step S9304: NO), it is determined whether the reset button 68c has been pressed (step S9305). When the reset button 68c is pressed (step S9305: YES), it is conditioned that "1" is not set in the setting update display flag provided in the specific control work area 221 (step S9306: NO). ), the setting update display flag is set to "1" (step S9307), and the checking counter provided in the specific control work area 221 is cleared to "0" (step S9308).

The initial check period is canceled by clearing the checking counter to “0”. In addition, since the setting update display flag is set to "1", in the second timer interrupt processing (FIG. 134), an affirmative determination is made in step S9003 as already described, and the first to fourth notification display devices are provided. In the fifth display data buffer 275, display data for displaying that the setting value of the pachinko machine 10 is being updated in 201 to 204 and displaying the current setting value of the pachinko machine 10 is performed. It is stored (step S9004). As a result, similar to the 33rd embodiment, on the first to fourth notification display devices 201 to 204, a display indicating that the setting value is being updated and a display indicating the current setting value. Is done.

If an affirmative decision is made in step S9306, or if the processing of step S9308 has been executed, the value of the set value counter in the work area 221 for specific control is incremented by 1 (step S9309). As a result, each time the reset button 68c is pressed once, the setting value is updated by one step. If the reset button 68c is not pressed (step S9305: NO) or if the value of the set value counter is incremented by 1, the process returns to step S9302. When it is determined that the value is 7 or more, "1" is set in the set value counter in step S9303. As a result, when the reset button 68c is pressed once in the situation of "setting 6", the process returns to "setting 1".

When the setting key insertion section 68a is turned off (step 9304: YES), the setting update display flag in the specific control work area 221 is cleared to "0" (step S9310). Thereby, on the first to fourth display devices 201 to 204, a display indicating that the setting value of the pachinko machine 10 is being updated and a display indicating the current setting value of the pachinko machine 10 are displayed. The state of being exposed is released. In this case, the display indicating the base value is started on the first to fourth notification display devices 201 to 204.

When the set value update process is executed as described above, the initial check period is canceled halfway and the first to fourth notification display devices 201 to 204 are currently operated, provided that the reset button 68c is pressed. The set value of is notified. As a result, when the supply of the operating power to the main CPU 63 is started and the main processing (FIG. 132) is started in the main CPU 63, the processing at the start of the supply of the operating power in the main processing is executed. Even if the initial check period is started and the check display is performed on the first to fourth notification display devices 201 to 204 in such a situation, the process at the start of the supply of the operating power is executed. In the case where the set value is updated under the situation, it is possible to cancel the initial check period and display the present set value on the first to fourth notification display devices 201 to 204. Therefore, the setting value can be updated while confirming the current setting value without waiting for the initial check period to elapse.

Further, even when the setting value update process (FIG. 137) is executed in the main process (FIG. 132), the initial check period is started first, so that the first to fourth notification display devices 201 to 204 are not displayed. It is possible to update the set value after confirming whether or not each of the display segments 321 to 324 in each can normally emit light. This makes it possible to accurately update the set value.

The initial check period is canceled when the reset button 68c is pressed to update the set value in the set value update process (FIG. 137). Accordingly, when the reset button 68c is pressed to update the set value, the initial check period is canceled accordingly, and the operability for canceling the initial check period can be improved. Become.

Returning to the description of the setting process in the normal state (FIG. 135 ), if the value of the checking counter is “0” and it is not the initial check period (step S9101: NO), the work area 223 for non-specific control is provided. It is determined whether the management start flag is set to "1" (step S9103). When "1" is not set in the management start flag (step S9103: NO), the setting process of the display before management start is executed for the first and second notification display devices 201 and 202 (step S9104). In the setting process, display data for setting all the display segments 321 and 322 in the first and second notification display devices 201 and 202 to the light emitting state is set in the fifth display data buffer 275. Note that the first and second notification display devices 201 and 202 are not limited to the configuration in which all the display segments 321 and 322 are in the light emitting state, and the first and second notification display devices 201 and A configuration may be adopted in which all of the display segments 321 and 322 in 202 each perform blinking display.

Thereafter, the calculation result data set in the display target setting area 276 in the non-specific control work area 223 is read (step S9105), and the read calculation result data is displayed in the third and fourth notification display devices 203 and 204. The display data to be applied is set in the fifth display data buffer 275 (step S9106). As described above, in the display process (FIG. 131), when the management start flag is not set to “1” (step S8701: NO), the base value is read from the current area 311 and the decimal point first in the read base value is set. The calculation result data corresponding to the digit of the digit and the digit of the second decimal point is set in the display target setting area 276 (step S8714). In step S9106, the calculation result data is set in the fifth display data buffer 275 as display data to be applied to the third and fourth notification display devices 203 and 204.

The display data set in the fifth display data buffer 275 in steps S9104 and S9106 is supplied to the display IC 266, whereby the first and second notification displays are displayed as shown in the explanatory diagram of FIG. 128(c). In a situation where all the display segments 321 and 322 in the devices 201 and 202 are in the light emitting state, the decimal point is the first decimal place of the base value calculated in the current calculation period in the third notification display device 203. Is displayed, and the number of the second decimal place of the base value calculated in the current calculation period is displayed on the fourth notification display device 204. In each of the first and second notification display devices 201 and 202, while displaying all the display segments 321 and 322 in the light emitting state, a number corresponding to the base value is displayed on the third and fourth notification display devices 203 and 204. By doing so, it becomes possible to let the manager of the game hall recognize that the base value currently notified is the base value in the situation where "1" is not set in the management start flag.

Further, in the situation where the management start flag is set to “1”, as described above, every time the display continuation period (specifically, 5 seconds) elapses, the current status area 311→first history area 312→first area In the predetermined order of the second history area 313 to the third history area 314, the base values to be notified are switched on the first to fourth notification display devices 201 to 204, while the management start flag is set to " In the situation where "1" is not set, the base value of the current area 311 is maintained as the notification target. As a result, when the operation check of the pachinko machine 10 is performed at the shipping stage of the pachinko machine 10, it is possible to check the current base value at any timing.

When the management start flag is set to "1" (step S9103: YES), the display data set in the display target setting area 276 in the work area 223 for non-specific control is read, and the read display data is set to the first display data. 5 display data buffer 275 (step S9107). By supplying the display data to the display IC 266, if the base value of the current area 311 is the notification target, the display as shown in the explanatory diagram of FIG. 127A is used for the first to fourth notifications. If the base values of the first history area 312 are displayed on the display devices 201 to 204, the display as shown in the explanatory view of FIG. 127(b) is displayed for the first to fourth notifications. If the base value of the second history area 313 is the notification target, the display as shown in the explanatory diagram of FIG. 127C is performed by the devices 201 to 204. 201 to 204, and if the base value of the third history area 314 is the notification target, the display as shown in the explanatory view of FIG. 127(d) is displayed on the first to fourth notification display devices 201. ~204.

After that, it is determined whether or not "1" is set in the initial display flag provided in the work area 223 for non-specific control (step S9108). As described above, the initial display flag is the first notification in order to notify that the base value is the initial calculation base value after the start of the calculation period in the situation where the base value of the current area 311 is the notification target. This is a flag for the main CPU 63 to specify that the status display device 201 and the second notification display device 202 should be displayed in blinking. When the initial display flag is set to "1" (step S9108: YES), the blinking setting process is executed for the first and second notification display devices 201 and 202 (step S9109).

In the blink setting process, when the display corresponding to the display data currently set in the fifth display data buffer 275 is displayed on the first and second notification display devices 201 and 202, the display is blinked. Settings to enable it. As the setting for making the display blinking, specifically, regarding the transmission of the display data to the first and second notification display devices 201 and 202, the display data currently set in the fifth display data buffer 275 is set. Corresponding data is transmitted to the display IC 266 until a predetermined lighting period (for example, 0.5 seconds) elapses, and then all the display segments 321 and 322 of the first and second notification display devices 201 and 202 are turned off. The state data is transmitted to the display IC 266 until a predetermined extinguishing period (for example, 0.5 seconds) elapses, and thereafter, the predetermined lighting period and the predetermined extinguishing period are alternately repeated. As a result, when the base value of the current area 311 is to be notified immediately after the new base value calculation period is started, the calculation initial display is performed on the first and second notification display devices 201 and 202. Therefore, it is possible for the manager of the game hall to understand that the current base value notified by the first to fourth notification display devices 201 to 204 is immediately after the start of the new calculation period. It will be possible.

Next, the display contents of the first to fourth notification display devices 201 to 204 when the supply of the operating power to the main CPU 63 is started will be described with reference to the time chart of FIG. 138. 138(a) shows the initial check period, and FIG. 138(b) shows the base value on the first to fourth notification display devices 201 to 204 in a situation where the management start flag is not set to "1". 138 (c) shows the display period before the start of management, in which the base values stored in the various areas 311 to 314 of the calculation result storage area 234 are sequentially notified by the first to fourth notification display devices 201 to 204. 138(d) shows a normal display period that is displayed, and FIG. 138(d) shows a display indicating that the set value of the pachinko machine 10 is being updated and a display indicating the current set value of the pachinko machine 10 is the first to fourth areas. FIG. 138(e) shows a display indicating that the setting value of the pachinko machine 10 is being confirmed and the current state of the pachinko machine 10 is shown. The display showing the set value shows the setting confirmation display period performed on the first to fourth notification display devices 201 to 204, and FIG. 138(f) shows the timing at which the reset button 68c is pressed.

First, when the supply of the operating power to the main CPU 63 is started in a situation where the management start flag is not set to "1", and the setting confirmation process (FIG. 136) and the process for starting the supply of the operating power (FIG. 136) and A case where the setting value update process (FIG. 137) is not executed will be described.

At the timing of t1, the initial check period is started as shown in FIG. 138(a). As a result, the check display is started on the first to fourth notification display devices 201 to 204 as shown in the explanatory view of FIG.

After that, at the timing of t2, as shown in FIG. 138(a), the initial check period ends without being canceled midway. In this case, the pre-management start display period is started at the timing of t2 as shown in FIG. 138(b). In the display period before the start of management, in the first notification display device 201 and the second notification display device 202, all the display segments 321 and 322 are in the light emitting state as shown in the explanatory diagram of FIG. On the third notification display device 203 and the fourth notification display device 204, numbers corresponding to the current base value are displayed.

After that, at the timing of t3, in the situation where the management start flag is not set to "1", and neither the open/close execution mode due to the big hit result nor the high frequency support mode, the gaming balls discharged from the game area PA The total number (that is, the total number of game balls supplied to the game area PA) reaches the management start reference number which is smaller than the shift reference number. As a result, the management start flag is set to "1", and the pre-management start display period ends as shown in FIG. 138(b). In this case, the normal display period is started at the timing of t3 as shown in FIG. 138(c). In the normal display period, as shown in FIGS. 127(a) to 127(d), the base values stored in the various areas 311 to 314 in the calculation result storage area 234 are the base values stored in the first to fourth notification display devices 201 to 204. Will be announced in sequence.

Next, when the supply of the operating power to the main CPU 63 is started in the situation where the management start flag is set to “1” and the process for starting the supply of the operating power is started, the setting confirmation process (FIG. 136). ) And the setting value updating process (FIG. 137) are not executed.

At the timing of t4, the initial check period is started as shown in FIG. 138(a). As a result, the check display is started on the first to fourth notification display devices 201 to 204 as shown in the explanatory view of FIG.

Then, at the timing of t5, as shown in FIG. 138(a), the initial check period ends without being canceled midway. In this case, the normal display period is started at the timing of t5 as shown in FIG. 138(c). In the normal display period, as shown in FIGS. 127(a) to 127(d), the base values stored in the various areas 311 to 314 in the calculation result storage area 234 are the base values stored in the first to fourth notification display devices 201 to 204. Will be announced in sequence.

Next, when the supply of the operating power to the main CPU 63 is started in the situation where the management start flag is set to “1”, and the setting value updating process (FIG. 137) is performed in the process when the supply of the operating power is started. ) Will be described.

At the timing of t6, the initial check period starts as shown in FIG. 138(a). As a result, the check display is started on the first to fourth notification display devices 201 to 204 as shown in the explanatory view of FIG.

After that, the set value updating process (FIG. 137) is started in the middle of the initial check period, and the reset button 68c is pressed at the timing of t7 as shown in FIG. 138(f). As a result, at the timing of t7, the initial check period is ended midway as shown in FIG. 138(a), and at the timing of t7, the setting updating display period is started as shown in FIG. 138(d). It

After that, at the timing of t8, the setting update display period ends as shown in FIG. 138(d). In this case, the normal display period is started at the timing of t8 as shown in FIG. 138(c). In the normal display period, as shown in FIGS. 127(a) to 127(d), the base values stored in the various areas 311 to 314 in the calculation result storage area 234 are the base values stored in the first to fourth notification display devices 201 to 204. Will be announced in sequence.

Next, when the supply of the operating power to the main CPU 63 is started in the situation where the management start flag is set to “1” and the process for starting the supply of the operating power is started, the setting confirmation process (FIG. 136). ) Will be described.

At the timing of t9, the initial check period starts as shown in FIG. 138(a). As a result, the check display is started on the first to fourth notification display devices 201 to 204 as shown in the explanatory view of FIG.

After that, the setting confirmation process (FIG. 136) is started in the middle of the initial check period, and the reset button 68c is pressed at the timing of t10 as shown in FIG. 138(f). As a result, at the timing of t10, the initial check period is ended midway as shown in FIG. 138(a), and at the timing of t10, the setting confirmation display period is started as shown in FIG. 138(e). It

Then, at the timing of t11, the setting confirming display period ends as shown in FIG. 138(e). In this case, the normal display period is started at the timing of t11 as shown in FIG. 138(c). In the normal display period, as shown in FIGS. 127(a) to 127(d), the base values stored in the various areas 311 to 314 in the calculation result storage area 234 are the base values stored in the first to fourth notification display devices 201 to 204. Will be announced in sequence.

It should be noted that when the supply of the operating power to the main CPU 63 is started in a situation where the management start flag is not set to "1", and the setting confirmation process (FIG. 136) is performed in the process when the supply of the operating power is started. Alternatively, when the setting value update process (FIG. 137) is executed and the initial check period is canceled midway, the pre-management start display period is started after the setting update display period or the setting confirmation display period is ended. It will be.

According to this embodiment described in detail above, the following excellent effects are exhibited.

As a check display, an initial check period may occur in which each of the display segments 321 to 324 in each of the first to fourth notification display devices 201 to 204 is in a light emitting state. This makes it possible to confirm whether or not each of the display segments 321 to 324 is in a light emitting state, and confirms whether or not the first to fourth notification display devices 201 to 204 are normal. It becomes possible to do.

When the supply of operating power to the main CPU 63 is started, the initial check period of the first to fourth notification display devices 201 to 204 is started. Accordingly, when the supply of the operating power is started, it is possible to early confirm whether or not the first to fourth notification display devices 201 to 204 are normal.

Each time the supply of operating power to the main CPU 63 is started, the initial check period of the first to fourth notification display devices 201 to 204 is started. This makes it possible to check whether or not the first to fourth notification display devices 201 to 204 are normal each time the supply of operating power is started.

When the supply of operating power to the main CPU 63 is started, the initial check period of the first to fourth notification display devices 201 to 204 is started without requiring a special operation. As a result, it becomes possible to facilitate the work of confirming whether or not the first to fourth notification display devices 201 to 204 are normal.

Even if the initial check period has not elapsed, if the cancellation trigger occurs, the check display on the first to fourth notification display devices 201 to 204 is terminated halfway. As a result, even during the initial check period, it is possible to terminate the check display and display another display on the first to fourth notification display devices 201 to 204.

When the supply of operating power to the main CPU 63 is started and before the process for controlling the progress of the game is executed, the initial check period is started and the first to fourth notification display devices 201 to 201 At 204, the display for checking is started. This makes it possible to confirm whether or not the first to fourth notification display devices 201 to 204 are normal before the game is started.

Start of supply of operating power in a configuration in which predetermined setting-related processing such as setting confirmation processing (FIG. 136) and setting value updating processing (FIG. 137) is executed in a situation where processing at the start of supply of operating power is being executed The initial check period is started in the situation where the hour process is being executed. This makes it possible to aggregate not only the predetermined setting-related processing but also the processing for starting the initial check period with respect to the processing when the supply of the operating power is started.

In the setting confirmation process (FIG. 136) and the set value update process (FIG. 137), in the configuration in which the display corresponding to the current set value is performed on the first to fourth notification display devices 201 to 204, these predetermined settings are performed. Before the related processing is executed, the initial check period is started, and the check display is started on the first to fourth notification display devices 201 to 204. Thereby, after confirming whether or not the first to fourth notification display devices 201 to 204 are normal, the current set values are confirmed using the first to fourth notification display devices 201 to 204. It becomes possible to do. Therefore, it becomes possible to accurately confirm the set value.

Based on the fact that the setting confirmation process (FIG. 136) or the set value update process (FIG. 137) is executed in the situation of the initial check period, even if the initial check period has not elapsed, the first to fourth notifications The display for checking on the display devices 201 to 204 is terminated halfway. Accordingly, when the setting confirmation process (FIG. 136) or the setting value update process (FIG. 137) is executed, the first to fourth notification display devices 201 to 201 do not have to wait for the initial check period to elapse. It becomes possible to display the present set value on the first to fourth notification display devices 201 to 204 by terminating the checking process in 204. Therefore, it becomes possible to confirm the current set value at an early stage.

When the setting confirmation process (FIG. 136) or the set value update process (FIG. 137) is executed in the situation of the initial check period and the reset button 68c is pressed, the initial check period has elapsed. Even if it does not exist, the check display on the first to fourth notification display devices 201 to 204 is terminated halfway. This makes it possible to end the initial check period at an arbitrary timing after the setting confirmation process (FIG. 136) or the set value update process (FIG. 137) is started. For example, when the setting confirmation process (FIG. 136) or the setting value update process (FIG. 137) is started, the game hall manager is sufficiently aware that the first to fourth notification display devices 201 to 204 are normal. After confirming the above, it is possible to end the check display and start displaying the current set value on the first to fourth notification display devices 201 to 204.

Further, in the set value updating process (FIG. 137), the reset button 68c is pressed to update the set value to be selected. In this case, when the reset button 68c is pressed as described above, the check display is ended and the current set value display is started on the first to fourth notification display devices 201 to 204. By doing so, it is not necessary to perform a dedicated operation for ending the check display and starting the display of the current set value. Therefore, it becomes possible to improve the workability of the work for updating the set value.

The calculation result storage area 234 stores a plurality of base values derived by using the information in the normal counter area 231 in different periods. As a result, it is possible to grasp the base value in a plurality of periods, so that it is possible to accurately grasp the ratio of the number of prize balls to the number of game balls supplied to the game area PA.

The calculation result storage area 234 is provided with a current area 311 in which the latest base value is stored, and first to third history areas 312 to 314 in which base values derived before that are stored. There is. As a result, the ratio of the number of prize balls to the number of game balls supplied to the game area PA can be grasped not only in the latest but also in the past.

The base value that is repeatedly calculated in a relatively short cycle before one calculation period elapses is stored in the current area 311 and the base value calculated when one calculation period elapses is the first to third values. The history areas 312 to 314 are stored. This makes it possible to grasp the most recent ratio of the number of prize balls to the number of game balls supplied to the game area PA, and to grasp the above-mentioned ratio in the unit of one calculation period. Is possible. Also, since the base values in the unit of one calculation period are stored in the first to third history areas 312 to 314, the number of base values stored in the first to third history areas 312 to 314 is suppressed. It becomes possible.

Based on the elapse of one calculation period, the various counters 231a to 231e in the normal counter area 231 are cleared to "0". This makes it possible to reduce the required storage capacity in the normal counter area 231. Even if the various counters 231a to 231e in the normal counter area 231 are configured to be cleared to "0" as described above, the base values calculated when one calculation period elapses are the first to third values. Since the history areas 312 to 314 are stored, the ratio of the number of prize balls to the number of game balls supplied to the game area PA in the past calculation period can be grasped later.

A plurality of history areas 312 to 314 are provided as areas for storing past base values. This makes it possible to compare the base values in a plurality of past calculation periods.

The base values stored in each of the current area 311, the first history area 312, the second history area 313, and the third history area 314 are sequentially displayed on the first to fourth notification display devices 201 to 204. Thereby, it becomes possible to individually grasp the base values in a plurality of calculation periods while suppressing the number of the notification display devices 201 to 204.

Even when the process at the time of starting the supply of the operating power is being executed, the occurrence of the power outage is monitored and the occurrence of the power outage is identified by executing the power outage information storage process (step S8901). The power outage process is executed. As a result, when a power outage occurs in a situation where the process at the start of supplying the operating power is being executed, it is possible to appropriately deal with it.

In the configuration in which the power outage information storage process (step S8901) is included in the first timer interrupt process (FIG. 133), the first timer interrupt process is executed even if the process at the start of supplying the operating power is being executed. It starts by interrupting. As a result, it is possible to regularly monitor the occurrence of a power failure even in the situation where the process at the start of supplying the operating power is being executed.

The first timer interrupt process (FIG. 133) is activated by interruption even in a situation where the residual process is executed after the process at the start of supplying the operating power is completed. As a result, it is possible to regularly monitor the occurrence of a power failure in a situation where the process at the start of supplying the operating power is being executed by using the first timer interrupt process that is activated by interrupting the residual process. Become.

When the first timer interrupt process (FIG. 133) is started by interruption in the situation where the process at the time of starting the supply of the operating power is being executed, the start-up process in progress flag provided in the work area 221 for specific control indicates “ Since "1" is set, the process for advancing the game is not executed. As a result, even if the process at the time of starting the supply of the operating power is being executed, the first timer interrupt process is interrupted and activated to periodically monitor the occurrence of the power failure. It is possible to prevent the process for advancing the game from being executed in the situation where the process at the start of supply is being executed.

In the configuration in which the setting value update processing (FIG. 137) is executed in the situation where the processing at the time of starting the supply of the operating power is executed, the power failure information Storage processing (step S8901) is executed. As a result, even if a power failure occurs during the setting of the setting value to be used, it is possible to appropriately cope with it.

The check display of the first to fourth notification display devices 201 to 204 is not limited to the configuration that is ended when the initial check period elapses, and an operation for ending the check display is performed. The check display may be continued until. As the operation for ending the operation, for example, the reset button 68c may be operated regardless of whether any one of the setting confirmation processing (FIG. 136) and the setting value update processing (FIG. 137) is executed. Of course, the operation unit other than the reset button 68c may be operated. In this case, the check display is continued on the first to fourth notification display devices 201 to 204 until it is time to confirm the base value or the set value on the first to fourth notification display devices 201 to 204. Therefore, it becomes possible to confirm the base value or the set value after confirming whether or not the first to fourth notification display devices 201 to 204 are normal. Moreover, since the check display is ended based on the operation of the operation unit, the check display can be ended at a desired timing.

Further, when a predetermined operation unit such as the update button 68b or the reset button 68c is operated regardless of whether or not the supply of operating power is started, the first to fourth notification display devices 201 to 204 are used for checking. The display may be started. In this case, the check display can be started at a desired timing when confirming the base value or the set value. Further, in the configuration, the check display may be terminated when a predetermined period (for example, 5 seconds) has passed, and the predetermined operation unit operated to start the check display or another operation unit different from the predetermined operation unit. The check display may be terminated when the operation unit is operated.

Further, when supply of operating power to the main CPU 63 is started in a state where a specific operation unit other than the reset button 68c such as the update button 68b is operated, the first to fourth notification display devices 201 to 204 are displayed. The check display may not be started when the check display is started and the supply of operating power to the main CPU 63 is started without operating the specific operation unit. In this case, in the configuration in which the check display is performed when the supply of the operating power is started, it is possible to select whether or not the check display is started by the operation of the game hall manager.

Further, the base value is not limited to the configuration in which the base value is displayed on the first to fourth notification display devices 201 to 204 regardless of whether or not the gaming machine body 12 is in the open state. When the open state is specified based on the detection result of the main body open sensor 96, the base value may be displayed on the first to fourth notification display devices 201 to 204. In this case, when the gaming machine main body 12 is in the open state, first the check display of the first to fourth notification display devices 201 to 204 is started, and then the first to fourth notification display devices 201 to 201. The base value may be displayed at 204. Thereby, before confirming the base value, it is possible to confirm whether or not the first to fourth notification display devices 201 to 204 are normal. Further, in the configuration, the check display may be terminated when a predetermined period (for example, 5 seconds) has passed, and the predetermined operation unit operated to start the check display or another operation unit different from the predetermined operation unit. The check display may be terminated when the operation unit is operated.

Further, when the main process (FIG. 132) is started in a state where the condition for executing the setting confirmation process (FIG. 136) is satisfied, the check displays of the first to fourth notification display devices 201 to 204 are displayed. If the main process is started without being started and the condition for executing the setting check process is not satisfied, the check display may be started. In this case, if it is confirmed that the set value is confirmed, it is possible to prevent the check display from being displayed.

Further, when the main process (FIG. 132) is started in a state where the condition for executing the set value update process (FIG. 137) is satisfied, the check display of the first to fourth notification display devices 201 to 204 is displayed. The check display may be started when the main process is started without being started and the condition for executing the set value update process is not satisfied. In this case, it is possible to prevent the check display from being displayed when it is determined that the setting value will be updated.

When the main process (FIG. 132) is started in a state where either the condition for executing the setting confirmation process (FIG. 136) or the condition for executing the setting value update process (FIG. 137) is satisfied, The main processing is performed in a state where both the condition for executing the setting confirmation process and the condition for executing the set value updating process are not satisfied without the check display of the first to fourth notification display devices 201 to 204 being started. The check display may be started when is started. In this case, when it is confirmed that the set value is confirmed or the set value is updated, it is possible to prevent the check display from being displayed.

In addition, the check display is not limited to the configuration in which the display segments 321 to 324 in each of the first to fourth notification display devices 201 to 204 are maintained in the light emitting state, and the first to fourth notifications are provided. Each of the display segments 321 to 324 in each of the display devices 201 to 204 may be in a blinking state. Further, in the check display, each of the display segments 321 to 324 in the first to fourth notification display devices 201 to 204 sequentially emits light one by one or a plurality of some of them, and the range of the initial check period Each of the display segments 321 to 324 may be in a light emitting state at least once.

Further, the processing for causing the first to fourth notification display devices 201 to 204 to perform the check display is not limited to the configuration executed as the processing corresponding to the specific control, and the processing corresponding to the non-specific control is performed. It may be configured to be executed as.

When the base value is not stored in any of the first to third history areas 312 to 314 of the calculation result storage area 234, the history areas 312 to 314 are displayed in the first to fourth notification display devices 201. It is also possible to adopt a configuration in which the notification is not made in steps 204 to 204. In this case, for example, when the base value is stored in the current area 311 and the first history area 312 while the base value is not stored in the second history area 313 and the third history area 314, the display continuation period , The notification target in the first to fourth notification display devices 201 to 204 is switched between the current status area 311 and the first history area 312, and the second history area 313 and the third history area 314 become It will not be subject to notification.

In addition, the present value area 311, the first history area 312, the second history area 313, and the third history area 314 of the calculation result storage area 234 store base values represented as decimals up to the second decimal place. Although the configuration is not limited to this, the configuration may be such that information on a combination of the first decimal point number and the second decimal point digit of the base value is stored. The total payout number of game balls to enable calculation (K91 x "number of prize balls for winning in the general winning opening 31" + K92 x "number of prize balls for winning in the special electric prize winning device 32" + K93 x "No. A combination of the number of prize balls for winning in one working opening 33+K94דthe number of winning balls for winning in the second working opening 34)” and the total number of gaming balls discharged from the game area PA (K91+K92+K93+K94+K95). The information may be stored. In the former case, the information of the various areas 311 to 314 can be set as it is in the display target setting area 276, and in the latter case, after the base value is calculated using the information of the various areas 311 to 314, Information on the first decimal place number and the second decimal place number extracted from the base value is set in the display target setting area 276.

Further, the calculation result storage area 234 may have a configuration in which only the current state area 311 and the first history area 312 are provided as areas for storing the base value, and the current state area 311, the first history area 312, and the first history area 312 and the first history area 312 may be provided. The configuration may be such that only the two history areas 313 are provided. Further, it may be configured such that four or more areas are provided as a history area for storing information on past base values.

Further, in the calculation result storage area 234, the various areas 311 to 314 are fixed on the address, and the base value is not limited to be shifted in the various areas 311 to 314 as necessary, and the various areas 311 are not limited. ˜314 may be provided as a ring buffer.

Further, instead of the configuration in which the base value is calculated as the mode information, the configuration in which the 61st parameter to the 68th parameter are calculated as in the fifteenth embodiment may be adopted. In this case, all of the 61st to 68th parameters may be stored in each of the current state area 311, the first history area 312, the second history area 313, and the third history area 314 of the calculation result storage area 234. The present area 311 may store some parameters, such as 61st to 68th parameters, but the 1st to 3rd history areas 312 to 314 may store only 61st parameters.

Further, in addition to or instead of the base value as the aspect information, the probability of occurrence of the jackpot result may be calculated and stored, or the probability of occurrence of the high frequency support mode may be calculated and stored.

Further, the trigger for shifting the base value in the various areas 311 to 314 in the calculation result storage area 234 is limited to when the total number of game balls discharged from the game area PA is equal to or larger than the shift reference number. Alternatively, the shift may be performed when a predetermined period (e.g., 8 hours) has elapsed, or the shift may be performed when the supply of operating power to the main CPU 63 is stopped. The shift may be performed when the supply of operating power to the CPU 63 is started, or the shift may be performed when the set value of the pachinko machine 10 is changed. Further, there may be a plurality of types of triggers for shifting.

Until the management start flag provided in the non-specific control work area 223 is set to "1", the display segments 321 and 322 in the first and second notification display devices 202 are in the light emitting state. However, the display segments 321 and 322 in each of the first and second notification display devices 202 may be in a blinking state. Also, until the management start flag is set to "1", "bL.---"→"b1.---"→"b2.---"→ in the first to fourth notification display devices 201 to 204. The display of "b3.---" may be repeated.

In addition, until the management start flag provided in the work area 223 for non-specific control is set to "1", the display segments 321 to 324 in each of the first to fourth notification display devices 201 to 204 are The display segments 321 and 322 in each of the first and second notification display devices 201 and 202 are in the light emission state or the blinking state without the check display being in the light emission state, and the third and fourth notifications are performed. For example, the display corresponding to the current base value may be displayed on the display devices 203 and 204, and the display corresponding to the fact that the management start flag is not set to "1" may be performed.

In addition, when the game stop flag is set to "1" because the power failure flag is not set to "1" or the checksums do not match, the progress of the game is stopped. In the display devices 201 to 204, each display segment 321 to 324 may be in a light emitting state as in the check display, or each display segment 321 to 324 may be in a blinking state.

The display control of the first to fourth notification display devices 201 to 204 is not limited to the configuration performed by the main CPU 63, and may be performed by a dedicated control unit. The display control device 82 may also be used. In this case, when displaying the base value on the first to fourth notification display devices 201 to 204, the base value to be notified is transmitted from the main CPU 63 to the control means that is the control subject, and When the set values are displayed on the fourth notification display devices 201 to 204, the set values to be notified are transmitted from the main CPU 63 to the control means serving as the control subject. When the main CPU 63 executes the process at the time of starting the supply of the operating power, the first to fourth notification display devices 201 to 204 are displayed in the situation where the process at the start of supplying the operating power is being executed. Thus, the information corresponding to the start of the check display is transmitted from the main CPU 63 to the control means that is the control subject so that the check display is started.

<Thirty-sixth embodiment>
In this embodiment, the processing configuration of the main processing executed by the main CPU 63 is different from that in the 35th embodiment. The configuration different from that of the 35th embodiment will be described below. The description of the same configuration as the thirty-fifth embodiment is basically omitted.

FIG. 139 is a flowchart showing the main processing executed by the main CPU 63 in this embodiment. The processes of steps S9401 to S9426 in the main process are executed by using the program for specific control and the data for specific control in the main CPU 63.

In steps S9401 to S9403, the same processing as steps S8801 to S8803 of the main processing (FIG. 132) in the thirty-fifth embodiment is executed. After that, interrupt permission is set (step S9404). As a result, the first timer interrupt process (FIG. 133) is interrupted and activated in the first interrupt cycle, and the second timer interrupt process (FIG. 134) is interrupted and activated in the second interrupt period. However, since "1" is set in the start-up processing flag in step S9403, even if the first timer interrupt processing is activated, power failure monitoring and various counters among various processing of the first timer interrupt processing are performed. While the processing for updating and fraud monitoring is executed, the first timer interrupt processing is ended without executing the processing for advancing the game.

After that, information corresponding to the initial check period (specifically, 5 seconds) is set in the checking counter provided in the work area 221 for specific control (step S9405). The value set in the checking counter is decremented by 1 each time the second timer interrupt process (FIG. 134) is activated, as in the 35th embodiment. When the value of 1 or more is set in the checking counter, the check display is performed on the first to fourth notification display devices 201 to 204 as in the 35th embodiment.

After that, it is determined whether or not the value of the checking counter is “0” (step S9406). Then, the process waits in step S9406 until the value of the checking counter reaches "0". As a result, the check display on the first to fourth notification display devices 201 to 204 is continued until the initial check period set in step S9405 has elapsed.

After that, the processes of steps S9407 to S9426 are executed. The processing contents of these steps S9407 to S9426 are the same as those of steps S8806 to S8825 of the main processing (FIG. 132) in the 35th embodiment.

According to the above configuration, when the supply of the operating power to the main CPU 63 is started and the processing at the start of the supply of the operating power is started in the main CPU 63, the first to fourth notification display devices 201 to 204 are displayed. The check display is displayed, and the progress of the process at the start of supplying the operating power is stopped until the initial check period elapses in that situation. This makes it possible to prevent the setting confirmation and the setting value update from being executed in the middle of the initial check period, and it is possible to suppress an increase in the processing load. Further, it becomes possible to prevent the game from being started in the middle of the initial check period.

<Thirty-seventh embodiment>
In this embodiment, the processing configuration of the main processing executed by the main CPU 63 is different from that in the 35th embodiment. The configuration different from that of the 35th embodiment will be described below. The description of the same configuration as the thirty-fifth embodiment is basically omitted.

FIG. 140 is a flowchart showing the main processing executed in the main CPU 63 in this embodiment. The processes of steps S9501 to S9525 in the main process are executed by using the specific control program and the specific control data in the main CPU 63.

In steps S9501 to S9518, the same processes as steps S7901 to S7918 of the main process (FIG. 114) in the thirty-third embodiment are executed. After that, information corresponding to the initial check period (specifically, 5 seconds) is set in the checking counter provided in the work area 221 for specific control (step S9519). The value set in the checking counter is decremented by 1 each time the second timer interrupt process (FIG. 134) is activated, as in the 35th embodiment. When the value of 1 or more is set in the checking counter, the check display is continued on the first to fourth notification display devices 201 to 204 as in the 35th embodiment.

After that, the processing from step S9520 is executed. The processing contents of steps S9520 to S9525 are the same as the steps S7919 to S7924 of the main processing (FIG. 114) in the thirty-third embodiment.

According to the above configuration, when the supply of the operating power to the main CPU 63 is started, the residual processing is performed after the processing at the start of the supply of the operating power (steps S9501 to S9518) is completed in the main CPU 63. Before (Step S9522 to Step S9525) is started, the initial check period is started. Accordingly, since it is not necessary to control the initial check period in the situation where the processing at the start of supplying the operating power is executed, the processing load in the situation where the processing at the start of supplying the operating power is executed is reduced. It becomes possible.

The setting confirmation process (step S9514) and the set value update process (step S9518) are executed as the process at the start of the supply of the operating power, whereas the process at the start of the supply of the operating power is completed during the initial check period. It will be started later. Accordingly, even if the check display is performed on the first to fourth notification display devices 201 to 204 during the initial check period, the set values are displayed using the first to fourth notification display devices 201 to 204. It becomes possible not to affect.

When the supply of operating power to the main CPU 63 is started, either the setting confirmation process (step S9514) or the set value update process (step S9518) is executed, and the setting confirmation process (step S9518). In either case where neither S9514) nor the set value update processing (step S9518) is executed, the check display is performed on the first to fourth notification display devices 201 to 204. This makes it possible to confirm whether or not the first to fourth notification display devices 201 to 204 are normal regardless of the situation when the supply of the operating power to the main CPU 63 is started.

In the main process (FIG. 140) of the main CPU 63, when either the setting confirmation process (step S9514) or the set value update process (step S9518) is executed, and the setting confirmation process (step S9514) and setting This is a process that is commonly executed regardless of whether neither the value update process (step S9518) is executed, and either the setting confirmation process (step S9514) or the set value update process (step S9518). When the execution is performed, the first to fourth notification display devices 201 to 204 are checked as the processing whose execution order is later than those of the setting confirmation processing (step S9514) and the setting value update processing (step S9518). The process to start the message display is set. In this way, the processing for starting the check display on the first to fourth notification display devices 201 to 204 is set as the common processing, so that the processing configuration is simplified and excellent as already described. It is possible to achieve the effect.

Even when the check display is being executed on the first to fourth notification display devices 201 to 204, the main CPU 63 can start the process for advancing the game. Thereby, even if the check display is performed on the first to fourth notification display devices 201 to 204 after the setting confirmation process (step S9514) or the set value update process (step S9518) is executed, the game is played. It is possible to prevent the start timing of the processing for advancing from being delayed.

Note that the processing after step S9520 may not be started until the initial check period elapses. In this case, it is possible to prevent the game from being started in the situation where the check display is being performed on the first to fourth notification display devices 201 to 204.

<38th Embodiment>
In the present embodiment, the processing configuration of the setting processing in normal time executed by the main CPU 63 is different from that in the 35th embodiment. The configuration different from that of the 35th embodiment will be described below. The description of the same configuration as the thirty-fifth embodiment is basically omitted.

FIG. 141 is a flow chart showing the setting processing in normal time in this embodiment, which is executed by the main CPU 63. The processes of steps S9601 to S9605 in the normal setting process are executed by using the specific control program and the specific control data in the main CPU 63.

First, it is determined whether or not "1" is set in the management start flag provided in the work area 223 for non-specific control (step S9601). If the management start flag is not set to "1" (step S9601: NO), the check display data is set in the fifth display data buffer 275 in the specific control work area 221 (step S9602). By supplying the data for the check display to the display IC 266, the check display is started on the first to fourth notification display devices 201 to 204. Specifically, all of the display segments 321 to 324 in the first to fourth notification display devices 201 to 204 are in a light emitting state. Thereby, the manager of the game hall can grasp whether or not each of the display segments 321 to 324 of the first to fourth notification display devices 201 to 204 can normally be in the light emitting state.

When "1" is set in the management start flag (step S9601: YES), the processes of steps S9603 to S9605 are executed. The processing contents of steps S9603 to S9605 are the same as those of steps S9107 to S9109 in the normal setting process (FIG. 135) in the thirty-fifth embodiment. By executing the processing of steps S9603 to S9605, the base values stored in the various areas 311 to 314 of the calculation result storage area 234 are sequentially notified on the first to fourth notification display devices 201 to 204. At the same time, when the base value of the current area 311 is notified immediately after the start of the new calculation period, the calculation initial display is performed on the first and second notification display devices 201 and 202.

According to the above configuration, when "1" is not set in the management start flag, the check period is displayed on the first to fourth notification display devices 201 to 204, which is an initial check period. Thereby, the situation where the initial check period is started when the supply of the operating power to the main CPU 63 is started is limited to the situation where the management start flag is not set to “1” at the shipping stage of the pachinko machine 10. Is possible.

<39th Embodiment>
In this embodiment, the configuration related to set values is different from that of the 33rd embodiment. The configuration different from that of the 33rd embodiment will be described below. The description of the same configuration as the thirty-third embodiment is basically omitted.

142(a) to 142(d) are explanatory views for explaining the setting correspondence storage area 325 provided in the main ROM 64.

In the setting correspondence storage area 325, the low probability mode win/loss table, the high probability mode win/fail table, and the setting confirmation process (FIG. 115) and the set value update process (FIG. 116) are associated with the set values of the pachinko machine 10. In, the display data of the set value used to display the current set value on the first to fourth notification display devices 201 to 204 is set. More specifically, the setting correspondence storage area 325 includes a first setting information storage area 325a, a second setting information storage area 325b, a third setting information storage area 325c, a fourth setting information storage area 325d, and a fifth setting information storage area. 325e and the sixth setting information storage area 325f are provided.

In each of the first to sixth setting information storage areas 325a to 325f, a storage area for storing the win/loss table of the low probability mode referred to when the win/loss lot mode is the low probability mode, and a win/loss lot mode. A storage area for storing the hit/disapproval table of the high-probability mode referred to in the high-probability mode, and the first to fourth notifications in the setting confirmation process (FIG. 115) and the setting value update process (FIG. 116). A storage area for storing display data of set values used to display the current set values on the display devices 201 to 204 is provided. In each of the first to sixth setting information storage areas 325a to 325f, a predetermined multi-byte area is secured as a storage area for storing the low probability mode hit/fail table, and the high probability mode hit/fail table is stored. A predetermined area of a plurality of bytes is secured as a storage area for storing the data, and a 1-byte area is secured as a storage area for storing the display data of the set value. Therefore, each of the first to sixth setting information storage areas 325a to 325f has a storage capacity of a plurality of bytes. In this case, the start address of the first setting information storage area 325a is A(1), the start address of the second setting information storage area 325b is A(2), and the third setting information storage area 325c. Has a start address of A(3), the start address of the fourth setting information storage area 325d is A(4), and the start address of the fifth setting information storage area 325e is A(5). The start address of the sixth setting information storage area 325f is A(6).

In the above configuration, in the pachinko machine 10 of the first embodiment in the present embodiment, as the set values of the pachinko machine 10, six setting values of “setting 1” to “setting 6” are set as in the 33rd embodiment. ing. In this case, the probabilities of jackpot results in the low-probability mode differ from each other in “setting 1” to “setting 6”, but the probabilities of jackpot results in the high-probability mode are the same. Therefore, as shown in FIG. 142(a), in the first setting information storage area 325a, the first low probability table LT() corresponding to "Setting 1" is stored in the storage area for storing the low probability mode win/loss table. 1) is stored, and a common high-probability table HT common to “Setting 1” to “Setting 6” is stored in the storage area for storing the high probability mode win/loss table. Display data for displaying "1" is stored in a storage area for storing display data. In the second setting information storage area 325b, a second low certainty probability table LT(2) corresponding to "setting 2" is stored in a storage area for storing a win/loss table in the low probability mode. A common high-probability hit/miss table HT that is common to "Setting 1" to "Setting 6" is stored in the storage area for storing the hit/no hit table, and the storage area for storing the display data of the set value is Display data for displaying "2" is stored.

The third setting information storage area 325c stores a third low certainty probability table LT(3) corresponding to “setting 3” in a storage area for storing the probability table of the low probability mode, and the high probability mode. In the storage area for storing the hit/no hit table, the common high-accuracy hit/miss table HT common to “Setting 1” to “Setting 6” is stored, and in the storage area for storing the display data of the set value, Display data for displaying "3" is stored. The fourth setting information storage area 325d stores a fourth low certainty probability table LT(4) corresponding to “setting 4” in a storage area for storing the low probability mode win/loss table, and the high probability mode. In the storage area for storing the hit/no hit table, the common high-accuracy hit/miss table HT common to “Setting 1” to “Setting 6” is stored, and in the storage area for storing the display data of the set value, Display data for displaying "4" is stored.

The fifth setting information storage area 325e stores a fifth low certainty hit/miss table LT(5) corresponding to "setting 5" in a storage area for storing the hit/miss table of the low probability mode, and the high probability mode. A common high-probability hit/miss table HT that is common to "Setting 1" to "Setting 6" is stored in the storage area for storing the hit/no hit table, and the storage area for storing the display data of the set value is Display data for displaying "5" is stored. In the sixth setting information storage area 325f, a sixth low certainty probability table LT(6) corresponding to “setting 6” is stored in a storage area for storing the low probability mode win/loss table, and the high probability mode is stored. A common high-probability hit/miss table HT that is common to "Setting 1" to "Setting 6" is stored in the storage area for storing the hit/no hit table, and the storage area for storing the display data of the set value is Display data for displaying "6" is stored.

In the case of the configuration of the first embodiment described above, the larger the set value, the higher the probability that the jackpot result will be in the low probability mode. On the other hand, the probability of a jackpot result in the high-probability mode is the same regardless of the set value. Since the probability of a jackpot result in the high-probability mode is 1/30, the probability of a jackpot result in the high-probability mode is higher than that in the low-probability mode in "setting 6" even in "Setting 1". There is a high probability.

In the first mode in which "setting 1" to "setting 6" are set as the set values, the process is executed in step S503 in order to execute the success/failure determination process in step S504 of the special figure variation start process (Fig. 13). The process of reading the hit/miss table will be described. FIG. 143 is a flowchart showing the read/write process of the win/fail table. Note that the processing of steps S9701 to S9705 in the read/write processing of the hit/miss table is executed using the program for specific control and the data for specific control in the main CPU 63.

First, the value of the set value counter provided in the work area 221 for specific control in the main RAM 65 is read (step S9701). Which of the first to sixth setting information storage areas 325a to 325f in the setting correspondence storage area 325 should be referred to by the setting value counter when reading the hit/miss table and when displaying the display data of the setting value? Is a counter for identifying the main CPU 63.

After that, among the first to sixth setting information storage areas 325a to 325f in the setting correspondence storage area 325, the storage area corresponding to the value of the setting value counter read in step S9701 is selected (step S9702). The set value counter is configured to take any value from "1" to "6" as in the 33rd embodiment. When the set value counter is "1", the first value When the setting information storage area 325a is selected and the setting value counter value is "2", the second setting information storage area 325b is selected, and when the setting value counter value is "3", the third setting information storage area 325b is selected. When the setting information storage area 325c is selected and the value of the setting value counter is "4", the fourth setting information storage area 325d is selected, and when the value of the setting value counter is "5" the fifth value is selected. The setting information storage area 325e is selected, and when the value of the setting value counter is "6", the sixth setting information storage area 325f is selected.

At the time of this selection, the correspondence table previously stored in the main ROM 64 is referred to. The correspondence table defines the correspondence relationship between the value of the setting value counter and the start addresses of the first to sixth setting information storage areas 325a to 325f. In detail, A(1) which is the start address of the first setting information storage area 325a is set in correspondence with the value of "1" of the set value counter, and corresponds to the value of "2" of the set value counter. Then, the start address A(2) of the second setting information storage area 325b is set, and the start address A of the third setting information storage area 325c is set in correspondence with the value "3" of the set value counter. (3) is set, the start address A(4) of the fourth setting information storage area 325d is set in correspondence with the value of "4" of the setting value counter, and "5" of the setting value counter is set. A(5), which is the start address of the fifth setting information storage area 325e, is set in correspondence with the value of "", and the sixth setting information storage area 325f is set in correspondence with the value of "6" of the setting value counter. The start address A(6) is set.

After that, if the current winning/discarding lottery mode is the low probability mode (step S9703: NO), the winning/discarding table of the low probability mode is read from the setting information storage areas 325a to 325f selected in step S9702 (step S9704). On the other hand, if the current winning/discarding lottery mode is the high probability mode (step S9703: YES), the winning/discarding table of the high probability mode is read from the setting information storage areas 325a to 325f selected in step S9702 (step S9705).

By executing the win/loss table reading process as described above, the win/loss table corresponding to the current win/loss lottery mode is read from the setting information storage areas 325a to 325f corresponding to the values of the set value counters. Then, in the win/loss determination process (step S504) of the special figure variation start process (FIG. 13), it is determined whether or not the current game time corresponds to the jackpot result by using the read win/loss table.

Next, a description will be given of the processing in the case where the second timer interrupt processing (FIG. 123) is activated by interruption while the setting value updating processing (step S7918) is being executed in the main processing (FIG. 114) in the main CPU 63. To do. In this case, in the second timer interrupt process (FIG. 123), the setting process for the fifth display data buffer 275 during the setting value update is executed (step S8403). FIG. 144 is a flowchart showing the setting process for the fifth display data buffer 275 during the setting update. The processes of steps S9801 to S9805 in the setting process are executed using the specific control program and the specific control data in the main CPU 63.

First, the value of the set value counter provided in the work area 221 for specific control in the main RAM 65 is read (step S9801). After that, among the first to sixth setting information storage areas 325a to 325f in the setting correspondence storage area 325, the storage area corresponding to the value of the set value counter read in step S9801 is selected (step S9802). The set value counter is configured to take any value from "1" to "6" as in the 33rd embodiment. When the set value counter is "1", the first value When the setting information storage area 325a is selected and the setting value counter value is "2", the second setting information storage area 325b is selected, and when the setting value counter value is "3", the third setting information storage area 325b is selected. When the setting information storage area 325c is selected and the value of the setting value counter is "4", the fourth setting information storage area 325d is selected, and when the value of the setting value counter is "5" the fifth value is selected. The setting information storage area 325e is selected, and when the value of the setting value counter is "6", the sixth setting information storage area 325f is selected. At the time of this selection, the correspondence table stored in advance in the main ROM 64 is referred to as in the read/write table reading process (FIG. 143).

After that, the display data of the setting value is read from the setting information storage areas 325a to 325f selected in step S9802 (step S9803). Then, the display data of the read set value is set in the fifth display data buffer 275 in the specific control work area 221 as display data to be applied to the fourth notification display device 204 (step S9804). In addition, display data for causing the first to third notification display devices 201 to 203 to display a display indicating that the setting value of the pachinko machine 10 is being updated is set in the fifth display data buffer 275. (Step S9805).

By performing the setting process for the fifth display data buffer 275 during the setting update as described above, the display corresponding to the display data set in the fifth display data buffer 275 in step S9805 is displayed as the first to the first. The third notification display devices 201 to 203 perform the display corresponding to the display data set in the fifth display data buffer 275 in step S9804 on the fourth notification display device 204. Thereby, as shown in the explanatory view of FIG. 124(a), for example, a display indicating that the setting value of the pachinko machine 10 is being updated and a display indicating the current setting value of the pachinko machine 10 are first. ~ The fourth notification display device 201 to 204.

The setting executed when the second timer interrupt process (FIG. 123) is activated by interruption while the setting confirmation process (step S7914) is being executed in the main process (FIG. 114) of the main CPU 63. Also in the setting process for the fifth display data buffer 275 during confirmation (step S8405), the setting of the display data of the set value is similar to the setting process for the fifth display data buffer 275 during the setting update (FIG. 144). The process of is executed.

Here, in the pachinko machine 10 of the first embodiment, as the set value of the pachinko machine 10, six setting values of “setting 1” to “setting 6” are set, but depending on the model and model of the pachinko machine 10, May use setting values less than 6 levels. Specifically, in the pachinko machine 10 of the second embodiment shown in the explanatory view of FIG. 142(b), three setting values of “setting 1”, “setting 3” and “setting 6” are set, In the pachinko machine 10 of the third embodiment shown in the explanatory view of 142(c), four setting values of “setting 1”, “setting 2”, “setting 3” and “setting 4” are set, and FIG. In the pachinko machine 10 of the fourth embodiment shown in the explanatory view of (d), only the one-step set value of “setting 1” is set. In this case, any of the pachinko machines 10 of the second to fourth modes, like the pachinko machine 10 of the first mode, enables the setting of the setting values in six stages, that is, the first to sixth setting information storages. A setting correspondence storage area 325 having areas 325a to 325f is used.

When the setting-corresponding storage area 325 is used in the pachinko machine 10 of the second mode, in detail, as shown in the explanatory diagram of FIG. 142(b), the first setting information storage area 325a and the fourth setting information storage area Various information corresponding to “setting 1” is stored in 325d. That is, in the first setting information storage area 325a and the fourth setting information storage area 325d, the first low-probability table LT(1) corresponding to "setting 1" is stored in the storage area for storing the low probability mode win/loss table. ) Is stored, and the first high-probability hit/miss table HT(1) corresponding to “setting 1” is stored in the storage area for storing the hit/miss table in the high probability mode. Display data for displaying “1” is stored in the storage area for storing.

Various information corresponding to “setting 3” is stored in the second setting information storage area 325b and the fifth setting information storage area 325e. That is, in the second setting information storage area 325b and the fifth setting information storage area 325e, the third low-probability/probability table LT(3) corresponding to “setting 3” is stored in the storage area for storing the probability table of the low probability mode. ) Is stored, and a third high-accuracy win/loss table HT(3) corresponding to “setting 3” is stored in the storage area for storing the win/loss table of the high probability mode, and the display data of the set value is displayed. Display data for displaying "3" is stored in the storage area for storing.

Various information corresponding to “setting 6” is stored in the third setting information storage area 325c and the sixth setting information storage area 325f. That is, in the third setting information storage area 325c and the sixth setting information storage area 325f, the sixth low certainty hit/miss table LT(6) corresponding to "setting 6" is stored in the storage area for storing the hit/miss table of the low probability mode. ) Is stored, and a sixth high-probability hit/miss table HT(6) corresponding to “setting 6” is stored in the storage area for storing the hit/miss table in the high probability mode. Display data for displaying "6" is stored in the storage area for storing.

In the case of the configuration of the second mode, even if the configuration corresponding storage area 325 having the first to sixth setting information storage areas 325a to 325f is used, these first to sixth setting information storage areas 325a to 325f are used. The set value of the number of stages is set to be less than the six which is the number of. Then, in the low-probability mode, the larger the set value, the higher the probability of a jackpot result, and in the high-probability mode, the larger the set value, the higher the probability of a jackpot result. The jackpot probability in the high-probability mode in “Setting 1” is higher than the jackpot probability in the low-probability mode in “Setting 6”.

In the case of the configuration of the second embodiment, in the read/write table (FIG. 143), the setting value counter corresponds to “setting 1” regardless of whether the value is “1” or “4”. The win/loss table is read, and the win/loss table corresponding to “setting 3” is read regardless of whether the value of the set value counter is “2” or “5”, and the value of the set value counter is In either case of "3" or "6", the win/loss table corresponding to "setting 6" is read.

The read/write table (FIG. 143) is configured to read the win/loss table from the setting information storage area 325 corresponding to the value of the set value counter regardless of the number of steps of the set value. As a result, even if three-stage set values are set, the processing configuration of the read/write table (FIG. 143) is the same as that when six-stage set values are set. It becomes possible.

In the case of the configuration of the second embodiment, when the setting correspondence storage area 325 capable of setting the setting values in six stages is used, since the setting values in three stages are set, the setting correspondence storage area 325 can set the setting values. It is possible to divide the number of stages of various set values by the number of stages of set values to be used. That is, the number of steps of the set value to be used is a divisor of the maximum number of steps of the set value that can be set in the setting correspondence storage area 325, and is a number different from the maximum number of steps. In this case, the same number of setting information storage areas 325a to 325f are assigned to each of the setting values to be used, and one set in which three setting values are arranged in ascending order one by one In such a case, the setting values are assigned to the first to sixth setting information storage areas 325a to 325f so that the group is repeated. Thus, when the reset button 68c is repeatedly operated from the situation where the value of the set value counter is "1" in the set value updating process (FIG. 116), the first to fourth notification display devices 201 to 204 are displayed. The set value displayed as is changed in the order of “1”→“3”→“6”→“1”→“3”→“6”→“1”→... That is, the display is changed to a display of a different set value for one operation of the reset button 68c, and a display in a certain mode is made when one set of display cycles indicates that the set value that can be set is displayed once. The orbit will be repeated. Therefore, it becomes easy to perform the update operation of the set value.

In the setting process (FIG. 144) for the fifth display data buffer 275 during the setting update, the set value is displayed from the setting information storage area 325 corresponding to the value of the set value counter regardless of the number of steps of the set value. This is a configuration for reading data. As a result, even when three-stage setting values are set, the processing configuration of the setting process (FIG. 144) can be made the same as that when six-stage setting values are set. It will be possible.

In the pachinko machine 10 of the second mode, various information corresponding to “setting 1” is stored in the first setting information storage area 325a and the second setting information storage area 325b, and the third setting information storage area 325c and the third setting information storage area 325c are stored. Various information corresponding to “setting 3” is stored in the fourth setting information storage area 325d, and various information corresponding to “setting 6” is stored in the fifth setting information storage area 325e and the sixth setting information storage area 325f. It may be configured to have. That is, the same number of setting information storage areas 325a to 325f are assigned to the respective setting values to be used, and the same setting values are consecutive in relation to the value of the setting value counter. The configuration may be set to 325a to 325f. In this case, when the reset button 68c is repeatedly operated from the situation where the value of the set value counter is "1" in the set value update process (FIG. 116), the first to fourth notification display devices 201 to 204 are displayed. The set value displayed as is changed in the order of “1”→“1”→“3”→“3”→“6”→“6”→“1”→...

For details about the case where the setting correspondence storage area 325 is used in the pachinko machine 10 of the third mode, as shown in the explanatory diagram of FIG. 142(c), the first setting information storage area 325a and the second setting information storage area are shown. Various information corresponding to "setting 1" is stored in 325b. That is, in the first setting information storage area 325a and the second setting information storage area 325b, the first low certainty probability table LT(1) corresponding to "setting 1" is stored in the storage area for storing the probability table of the low probability mode. ) Is stored, and a common high certainty hit/miss table HT that is common to “Setting 1” to “Setting 6” is stored in the storage area for storing the hit/miss table of the high probability mode, and the set value is displayed. Display data for displaying "1" is stored in a storage area for storing data.

Various information corresponding to “setting 2” is stored in the third setting information storage area 325c and the fourth setting information storage area 325d. That is, in the third setting information storage area 325c and the fourth setting information storage area 325d, the second low probability table LT(2) corresponding to “setting 2” is stored in the storage area for storing the low probability mode win/loss table. ) Is stored, and a common high certainty hit/miss table HT that is common to “Setting 1” to “Setting 6” is stored in the storage area for storing the hit/miss table in the high probability mode, and the set value is displayed. Display data for displaying "2" is stored in a storage area for storing data.

Various information corresponding to "setting 3" is stored in the fifth setting information storage area 325e. That is, in the fifth setting information storage area 325e, the third low-probability/probability table LT(3) corresponding to “setting 3” is stored in the storage area for storing the low/probability mode win/loss table, which is high. A common high certainty accuracy table HT that is common to “Setting 1” to “Setting 6” is stored in the storage area for storing the probability table of the probability mode, and a storage area for storing the display data of the set value. The display data for displaying "3" is stored.

Various information corresponding to "setting 4" is stored in the sixth setting information storage area 325f. That is, in the sixth setting information storage area 325f, a fourth low certainty probability table LT(4) corresponding to “setting 4” is stored in the storage area for storing the win/loss table of the low probability mode, which is high. A common high-precision probability table HT that is common to “Setting 1” to “Setting 6” is stored in the storage area for storing the probability table of the probability mode, and a storage area for storing display data of set values. The display data for displaying "4" is stored in.

In the case of the configuration of the third mode, even if the configuration corresponding storage area 325 having the first to sixth setting information storage areas 325a to 325f is used, these first to sixth setting information storage areas 325a to 325f are used. The set value of the number of stages is set to be smaller than the number of six. The probability of a big hit result in the low probability mode increases as the set value increases, and the probability of a big hit result in the high probability mode becomes the same regardless of the set value. Since the probability of a jackpot result in the high-probability mode is 1/30, the probability of a jackpot result in the high-probability mode is higher than that in the low-probability mode in “setting 4” even in “Setting 1”. There is a high probability.

In the case of the configuration of the third mode, in the read/write table (FIG. 143), the setting value counter corresponds to “setting 1” regardless of whether the value is “1” or “2”. The win/loss table is read, and the win/loss table corresponding to “setting 2” is read regardless of whether the value of the set value counter is “3” or “4”, and the value of the set value counter is In the case of "5", the win/loss table corresponding to "setting 3" is read, and in the case of the value of the set value counter being "6", the win/loss table corresponding to "setting 4" is read.

The read/write table (FIG. 143) is configured to read the win/loss table from the setting information storage area 325 corresponding to the value of the set value counter regardless of the number of steps of the set value. As a result, even if four-step set values are set, the processing configuration of the read/write table (FIG. 143) is the same as that when six-step set values are set. It becomes possible.

In the case of the configuration of the third embodiment, when the setting correspondence storage area 325 capable of setting setting values in 6 stages is used, since the setting values in 4 stages are set, the setting correspondence storage area 325 can set the setting values. The number of different set values cannot be divided by the number of set values to be used. In this case, two consecutive setting information storage areas 325a to 325d are assigned to each of "setting 1" and "setting 2" in relation to the value of the setting value counter, and "setting 3" and One setting information storage area 325e, 325f is allocated to each of the "settings 4". Thus, when the reset button 68c is repeatedly operated from the situation where the value of the set value counter is "1" in the set value updating process (FIG. 116), the first to fourth notification display devices 201 to 204 are displayed. The set value displayed as is changed in the order of “1”→“1”→“2”→“2”→“3”→“4”→“1”→...

In the setting process (FIG. 144) for the fifth display data buffer 275 during the setting update, the set value is displayed from the setting information storage area 325 corresponding to the value of the set value counter regardless of the number of steps of the set value. This is a configuration for reading data. As a result, even when four-stage setting values are set, the processing configuration of the setting process (FIG. 144) can be made the same as that when six-stage setting values are set. It will be possible.

In addition, in the setting value update process (FIG. 116), in order to change the display of the setting value on the first to fourth notification display devices 201 to 204 with respect to one operation of the reset button 68c, It is preferable that various pieces of information corresponding to the same set value are not set in consecutive set information storage areas 325a to 325f in relation to the value of the set value counter. For example, various information corresponding to "setting 1" is set in the first setting information storage area 325a, various information corresponding to "setting 2" is set in the second setting information storage area 325b, and third setting information storage area Various information corresponding to "setting 3" is set in 325c, various information corresponding to "setting 4" is set in the fourth setting information storage area 325d, and "setting 1" is set in the fifth setting information storage area 325e. A configuration is conceivable in which various information to be set is set and various information corresponding to “setting 2” is set in the sixth setting information storage area 325f. In this case, when the reset button 68c is repeatedly operated from the situation where the value of the set value counter is "1" in the set value update process (FIG. 116), the first to fourth notification display devices 201 to 204 are displayed. The set value displayed as is changed in the order of “1”→“2”→“3”→“4”→“1”→“2”→“1”→...

For details about the case where the setting correspondence storage area 325 is used in the pachinko machine 10 of the fourth mode, as shown in the explanatory diagram of FIG. 142(d), all of the first to sixth setting information storage areas 325a to 325f are described. Various information corresponding to "Setting 1" is stored in the. That is, in the first to sixth setting information storage areas 325a to 325f, the first low certainty hit/miss table LT(1) corresponding to "Setting 1" is stored in the storage area for storing the hit/miss table of the low probability mode. The common high-probability table HT, which is common to “Setting 1” to “Setting 6”, is stored in the storage area for storing the hit table of the high probability mode, and the display data of the set value is stored. Display data for displaying “1” is stored in the storage area for displaying.

In the case of the configuration of the fourth mode, only one type of setting value is set even in the configuration in which the setting correspondence storage area 325 having the first to sixth setting information storage areas 325a to 325f is used. Even if only one kind of setting value is set in this way, in the read/write table read processing (FIG. 143), the read/write table can be read from the setting information storage area 325 corresponding to the value of the set value counter. is there. As a result, even when only one type of setting value is set, the processing configuration of the read/write table (FIG. 143) is the same as the processing configuration when setting values in six stages. It becomes possible to do.

In the case of the configuration of the fourth embodiment, it is not basically necessary to execute the set value update processing (FIG. 116) because it is not necessary to set the set value, but if an abnormality occurs in the set value, The update process (FIG. 116) may be executed. In this case, "setting 1" is assigned to all of the first to sixth setting information storage areas 325a to 325f. Therefore, in the setting value updating process (FIG. 116), when the reset button 68c is repeatedly operated from the situation where the value of the setting value counter is "1", the first to fourth notification display devices 201 to 204 are used. The set value displayed is "1" → "1" → "1" → "1" → "1" → "1" → "1" → ... and the display of "1" is continued. It will be.

In the setting process (FIG. 144) for the fifth display data buffer 275 during the setting update, the set value is displayed from the setting information storage area 325 corresponding to the value of the set value counter regardless of the number of steps of the set value. This is a configuration for reading data. As a result, even when only one type of setting value is set, the processing configuration of the setting process (FIG. 144) should be the same as that when setting values of 6 levels are set. Is possible.

According to this embodiment described in detail above, the following excellent effects are exhibited.

Since the setting value to be used is set from the setting values of multiple stages corresponding to the advantage of the player, the player expects that a more advantageous setting value is to be used. It will be. In this case, in the pachinko machine 10 of the second form to the fourth form, the first predetermined number (specifically, 6) of setting information storage areas 325a to 325f are provided to store the win/loss table corresponding to the set values. In this configuration, the number of types of setting values to be used is smaller than the first predetermined number. As a result, it becomes possible to share the configuration relating to the setting-corresponding storage area 325 with the pachinko machine 10 of the first embodiment in which the number of types of setting values to be used is the first predetermined number, and change the number of types of setting values. In this case, the design work of the pachinko machine 10 can be easily performed.

In the set value update process (step S7918), the set value to be used is changed by changing the numerical information of the set value counter provided in the work area 221 for specific control every time the reset button 68c is operated. By using the win/loss table of the setting information storage areas 325a to 325f corresponding to the changed numerical information in the win/loss judgment process, the win/loss judgment process is executed in a manner corresponding to the setting value to be used. Become. In this case, each hit/miss table of set values that can be set is stored in at least one setting information storage area 325a to 325f, and is a part of the first predetermined number, and a plurality of setting information storages. Since the same win/loss table is stored in the areas 325a to 325f, the win/loss table is stored in all of the first predetermined number of setting information storage areas 325a to 325f. Thereby, while using the configuration in which the first predetermined number of setting information storage areas 325a to 325f are used as they are and the setting value counter is used to determine the setting value to be used, the setting value to be used is changed. It is possible to make the number of types smaller than the first predetermined number.

In this configuration, the win/loss table is read from the setting information storage areas 325a to 325f corresponding to the numerical value information of the set value counter, and the win/loss determination process is executed using the read win/loss table. As a result, even if the number of types of setting values to be used is less than the first predetermined number, the configuration for reading the win/loss table when executing the win/loss determination process can be used as it is. ..

In the situation where the set value update processing (step S7918) is executed, the display data of the set value is read from the set information storage areas 325a to 325f corresponding to the numerical information of the set value counter, and the read display data of the set value is read. The corresponding display is displayed on the fourth notification display device 204. As a result, even if the number of types of setting values to be used is less than the first predetermined number, the configuration for reading the display data of the setting values when executing the display corresponding to the setting values is used as it is. It becomes possible to do.

The number of steps of the setting value to be used is a divisor of the maximum number of steps of the setting value that can be set in the setting correspondence storage area 325, and is a number different from the maximum number of steps. In this case, the same number of setting information storage areas 325a to 325f are assigned to each of the setting values to be used, and one set in which three setting values are arranged in ascending order one by one In such a case, the setting values are assigned to the first to sixth setting information storage areas 325a to 325f so that the group is repeated. Thus, when the reset button 68c is repeatedly operated from the situation where the value of the set value counter is "1" in the set value updating process (FIG. 116), the first to fourth notification display devices 201 to 204 are displayed. The set value displayed as is changed in the order of “1”→“3”→“6”→“1”→“3”→“6”→“1”→... That is, the display is changed to a display of a different set value for one operation of the reset button 68c, and a display in a certain mode is made when one set of display cycles indicates that the set value that can be set is displayed once. The orbit will be repeated. Therefore, it becomes easy to perform the update operation of the set value.

In the configuration in which the high probability mode win/loss table does not change according to the set value, the high probability mode win/loss table is stored in the first to sixth setting information storage areas 325a to 325f of the setting correspondence storage area 325. Instead, the main ROM 64 may be stored in a storage area different from the setting correspondence storage area 325.

Further, when there is only one set value to be used, the win/loss table corresponding to the set value is set in only one set information storage area 325a to 325f and the remaining set information storage area 325a to The win/loss table may not be set in 325f. In addition, when the setting value to be used is a plurality of steps but the number of steps is smaller than the number of the first to sixth setting information storage areas 325a to 325f, the win/loss tables corresponding to the respective setting values are respectively set. The configuration may be such that only one corresponding setting information storage area 325a to 325f is set, and the remaining setting information storage areas 325a to 325f are not set to the win/fail tables. In the configuration, by setting the numerical information corresponding to the setting information storage areas 325a to 325f for which the win/loss table is not set as the numerical information that cannot be selected in the set value counter, the setting information storage area for which the win/loss table is not set It is possible to prevent 325a to 325f from being selected at the time of reading the win/fail table or reading the display data of the set value.

<40th Embodiment>
In the thirty-ninth embodiment described above, the setting correspondence storage area 325 capable of setting the setting values in six stages is used, but in the present embodiment, the setting correspondence storage area in which the setting values in three stages can be set is supported. The storage area 326 is used.

145(a) to 145(c) are explanatory views for explaining the setting correspondence storage area 326 stored in the main ROM 64 in advance.

The setting correspondence storage area 326 is provided with a first setting information storage area 326a, a second setting information storage area 326b, and a third setting information storage area 326c. In the pachinko machine 10 of the first embodiment shown in FIG. 145(a), various information corresponding to "setting 1" is set in the first setting information storage area 326a, and "setting 2" is set in the second setting information storage area 326b. Is set, and various information corresponding to "Setting 3" is set in the third setting information storage area 326c. That is, in the pachinko machine 10 of the first embodiment, the maximum number of settable values in the setting correspondence storage area 326 is set.

In the pachinko machine 10 of the second embodiment shown in FIG. 145(b), various information corresponding to “setting 1” is set in all of the first to third setting information storage areas 326a to 326c. That is, in the pachinko machine 10 of the second embodiment, only one type of set value is set by using the setting correspondence storage area 326 capable of setting the set value in three stages.

In the pachinko machine 10 of the third mode shown in FIG. 145(c), various information corresponding to “setting 1” is set in the first setting information storage area 326a and the second setting information storage area 326b, and the third setting is performed. Various information corresponding to “setting 3” is set in the information storage area 326c. That is, in the pachinko machine 10 of the third embodiment, the setting correspondence storage area 326 capable of setting the setting values in three steps is used to set the setting values in two steps.

According to the above configuration, the setting correspondence storage area 326 capable of setting the setting values in three steps is used in the second and third modes in which the setting values of the number of steps less than the setting values in three steps are used. The pachinko machine 10 can be used as it is. Further, as in the 39th embodiment, the processing configuration of the read/write table (FIG. 143) and the processing configuration of the setting process (FIG. 144) to the fifth display data buffer 275 during the setting update are as follows. ~ It becomes possible to use in common in the pachinko machine 10 of the third form.

<Forty-first embodiment>
In the present embodiment, when the setting confirmation process (step S7914) or the set value update process (step S7918) is executed in the main process (FIG. 114) in the main CPU 63, it is visible from the front side of the pachinko machine 10. The third embodiment is different from the thirty-third embodiment in that a predetermined notification is executed on the display unit. The configuration different from that of the 33rd embodiment will be described below. The description of the same configuration as the thirty-third embodiment is basically omitted.

FIG. 146( a) is an explanatory diagram for explaining various display units provided in a region visible from the front of the pachinko machine 10 through the window panel 52 that causes the front surface of the pachinko machine 10.

As various display parts, a special figure display part 37a, a special figure reservation display part 37b, a general figure display part 38a, and a general figure reservation display part 38b are provided. These functions are the same as those in the first embodiment. The special figure display portion 37a and the general figure display portion 38a are provided side by side, but the round display portion 330 is provided so as to be side by side with respect to the special figure display portion 37a and the general figure display portion 38a. Has been.

The round display section 330 has seven display segments 331 to 337 similarly to the special figure display section 37a and the general figure display section 38a. Each of the seven display segments 331 to 337 is a rod-shaped light emitting region having the same shape and the same size, and is arranged so as to generate the shape of "8". The seven display segments 331 to 337 are individually controlled to emit light.

In the round display section 330, the number of round games that occur in the opening/closing execution mode triggered by the jackpot result is notified. In the present embodiment, as a jackpot result that can be selected when the jackpot determination process is a jackpot, the first jackpot result that triggers a transition to the open/close execution mode in which the number of round game executions is relatively small, and the round game. There is a second jackpot result that triggers a transition to the open/close execution mode in which the number of times of execution of is relatively large. Specifically, the round game is executed twice in the opening/closing execution mode triggered by the first jackpot result, and the round game is executed 16 times in the opening/closing execution mode triggered by the second jackpot result.

The first jackpot result is a jackpot result in which the win/loss lottery mode becomes the low-probability mode and the support mode becomes the low-frequency support mode after the end of the opening/closing execution mode, and the win/win lottery mode has a high probability in the end/opening/closing execution mode. There is a big hit result that the support mode becomes the high frequency support mode as well as the mode. In addition, the second jackpot result is a jackpot result in which the win/loss lottery mode becomes the low-probability mode and the support mode becomes the low-frequency support mode after the end of the opening/closing execution mode, and the win/loss lottery mode has a high probability after the end of the opening/closing execution mode. There is a big hit result that the support mode becomes the high frequency support mode as well as the mode.

FIG. 146( b) is an explanatory diagram for explaining the display content of the round display unit 330.

The round display unit 330 displays at least a part of the display state from the non-display state in which all the display segments 331 to 337 are turned off when the open/close execution mode triggered by one of the jackpot results is started. The segments 331 to 337 are in a display state in which they emit light. In the situation where the open/close execution mode continues, the display content displayed on the round display section 330 at the start of the open/close execution mode is maintained. Then, when the opening/closing execution mode ends, the round display unit 330 changes from the display state to the non-display state.

In the open/close execution mode in which the round game is executed twice, as shown in FIG. 146(b), the first to fourth display segments 331 to 334 of the round display unit 330 are turned off, and the fifth segment is displayed. ~ The seventh display segments 335 to 337 are turned on. In the open/close execution mode in which 16 rounds of games are executed, as shown in FIG. 146(b), the first to fourth display segments 331 to 334 of the round display section 330 are turned on and the fifth is displayed. The seventh display segments 335 to 337 are turned off. Thereby, the manager of the game hall confirms the round display section 330 when the pachinko machine 10 is executing the opening/closing execution mode, and the opening/closing execution mode corresponds to any kind of opening/closing execution mode. It becomes possible to grasp whether or not.

When the set value update process (step S7918) is being executed in the main process (FIG. 114) in the main CPU 63, the round display unit 330 makes a corresponding display. Specifically, when the set value update processing (step S7918) is being executed, as shown in FIG. 146(b), the first display segment 331, the third display segment 333 of the round display unit 330, The fifth display segment 335 and the seventh display segment 337 are turned off, and the second display segment 332, the fourth display segment 334, and the sixth display segment 336 are turned on.

The display in the round display unit 330 corresponding to the set value update process (step S7918) is started when the set value update process (step S7918) is started, and is displayed when the set value update process (step S7918) is finished. Will be terminated. This display content is different from the display content displayed on the round display unit 330 when the open/close execution mode is executed, and further when the setting confirmation process (step S7914) described later is executed. It is also different from the display content displayed on 330. As a result, the game hall manager can easily confirm whether or not the setting value update processing (step S7918) is being performed by checking the round display portion 330. Further, such a grasp can be performed using the round display unit 330.

When the setting confirmation process (step S7914) is executed in the main process (FIG. 114) in the main CPU 63, the round display unit 330 displays a corresponding display. Specifically, when the setting confirmation process (step S7914) is being executed, as shown in FIG. 146(b), the first display segment 331, the third display segment 333 of the round display unit 330, The fifth display segment 335 and the seventh display segment 337 are turned on, and the second display segment 332, the fourth display segment 334, and the sixth display segment 336 are turned off.

The display in the round display unit 330 corresponding to the setting confirmation process (step S7914) is started when the setting confirmation process (step S7914) is started, and is displayed when the setting confirmation process (step S7914) is ended. Will be terminated. This display content is different from the display content displayed on the round display unit 330 when the open/close execution mode is executed, and is displayed on the round display unit 330 when the set value update processing (step S7918) is further executed. It is also different from the displayed content. As a result, the game hall manager can easily confirm by checking the round display section 330 whether or not the setting confirmation process (step S7914) is being executed. Further, such a grasp can be performed using the round display unit 330.

In the situation where the setting confirmation process (step S7914) and the setting value update process (step S7918) are executed in the main process (FIG. 114), the process for advancing the game is not executed. Therefore, the setting confirmation process (step S7914) and the set value update process (step S7918) are not executed in the situation where the open/close execution mode is being executed. Further, in the situation where one of the setting confirmation process (step S7914) and the setting value update process (step S7918) is being executed, the other is not executed. Therefore, even if the round display section 330 is also used as a display section for performing each display, the situation in which each display should be performed does not occur in duplicate.

The display contents of the round display unit 330 are not limited to the above display contents, and are arbitrary as long as it is possible to distinguish the respective situations from the display contents of the round display unit 330, for example, One of the display and set value update processing (step S7918) corresponding to the setting confirmation processing (step S7914) may be configured so that all of the first to seventh display segments 331 to 337 are turned on. Further, in one of the display and the set value update processing (step S7918) corresponding to the setting confirmation processing (step S7914), all of the first to seventh display segments 331 to 337 are turned on and the state is maintained. On the other hand, all of the first to seventh display segments 331 to 337 may be in a blinking state.

Further, instead of the configuration in which the display corresponding to the setting confirmation process and the display corresponding to the setting value update process are performed in the round display unit 330, the special figure display unit 37a may perform these displays, It is also possible to adopt a configuration in which these displays are performed on the public figure display unit 38a. Further, a display corresponding to the setting confirmation process is performed on any one of the special figure display section 37a, the general figure display section 38a, and the round display section 330, and the display is set on the other one display section. The display corresponding to the value update processing may be performed.

In addition, the hold information acquired based on the entry of the game ball into the first operating port 33 and the hold information acquired based on the entry of the game ball into the second operating port 34 are stored separately. As the special view display unit 37a, the first special view display unit in which the game times are triggered by the hold information corresponding to the first working port 33, and the game triggered by the hold information corresponding to the second working port 34 In the configuration provided with the second special figure display unit for executing the number of times, the first special figure display unit performs a display corresponding to the setting confirmation process and a display corresponding to the set value update process. Alternatively, the second special figure display unit may be configured to perform a display corresponding to the setting confirmation process and a display corresponding to the set value update process, and the first special figure display unit may correspond to the setting confirmation process. The second special figure display unit may perform a display corresponding to the setting value update processing.

Further, a configuration may be provided in which a dedicated display unit for displaying that the setting confirmation process is being executed is provided, and it is displayed that the setting value update process is being executed. May be provided with a dedicated display unit for displaying the setting confirmation process or the setting value update process. The display unit may be provided. In this case, the dedicated display unit may be display-controlled by the main CPU 63, or may be display-controlled by the sound emission control device 81 or the display control device 82.

<42nd Embodiment>
In this embodiment, the processing configurations of the main processing and the first timer interrupt processing are different from those of the 33rd embodiment. The configuration different from that of the 33rd embodiment will be described below. The description of the same configuration as the thirty-third embodiment is basically omitted.

FIG. 147 is a flowchart showing the main processing in this embodiment executed by the main CPU 63. The processes of steps S9901 to S9923 in the main process are executed by using the program for specific control and the data for specific control in the main CPU 63.

First, power-on initialization processing is executed (step S9901). In the power-on initialization process, for example, a predetermined wait time (specifically, 1 second) elapses after the main process is started, and the process waits without proceeding to the next process. In the predetermined period for this weight, the operation start and initial setting of the symbol display device 41 are completed. Also, access to the main RAM 65 is permitted.

Then, the internal function register setting process is executed (step S9902). In the internal function register setting process, similarly to step S7902 of the main process (FIG. 114) in the thirty-third embodiment, the first timer interrupt process (process that is activated by periodically interrupting the main process ( The interrupt period of FIG. 148) is set to the first interrupt period (specifically 4 milliseconds), and the second timer interrupt process (FIG. 123) is a process that is activated by periodically interrupting the main process. ) Is set to a second interrupt cycle (specifically, 2 milliseconds) which is shorter than the first interrupt cycle.

After that, the interrupt permission is set for the second timer interrupt process (FIG. 123) (step S9903). As a result, the second timer interrupt process (FIG. 123) is started by interrupting at the second interrupt cycle. On the other hand, in the first timer interrupt process (FIG. 148), the interrupt permission is not set. As a result, the first timer interrupt processing (FIG. 148) is still maintained in the interrupt disabled state.

Then, the processes of steps S9904 to S9917 are executed. The processing contents of these steps S9904 to S9917 are the same as the steps S7905 to S7918 of the main processing (FIG. 114) in the 33rd embodiment.

After the processes of steps S9904 to S9917 are completed, the interrupt permission is set for the first timer interrupt process (FIG. 148) (step S9918). As a result, the first timer interrupt process (FIG. 148) is started by interrupting at the first interrupt cycle. That is, the first timer interrupt process (FIG. 117) is activated by the first interrupt cycle, and the second timer interrupt process (FIG. 123) is activated by the second interrupt cycle. After that, in steps S9919 to S9923, the same processes as steps S7920 to S7924 of the main process (FIG. 114) in the thirty-third embodiment are executed.

FIG. 148 is a flowchart showing the first timer interrupt processing in this embodiment executed by the main CPU 63. It should be noted that the first timer interrupt process is periodically activated at the 4 ms cycle, which is the first interrupt cycle, as already described. Further, the program corresponding to the first timer interrupt processing is set to the program for specific control.

First, in order to prohibit the occurrence of the first timer interrupt process (FIG. 148) and the second timer interrupt process (FIG. 123), interrupt prohibition is set (step SA101). Since the generation of the first timer interrupt processing (FIG. 148) is prohibited and the generation of the first timer interrupt processing (FIG. 148) is prohibited, it is assumed that the first timer interrupt processing (FIG. 148) is being executed. Even if the first interrupt cycle has elapsed, it is possible to prevent the first timer interrupt processing (FIG. 148) from being repeatedly activated. Further, since the generation of the second timer interrupt process (FIG. 123) is prohibited, the second timer interrupt process (FIG. 123) is different from the first timer interrupt process (FIG. 148) even if the second interrupt cycle elapses. It is possible to prevent it from being interrupted and started.

Then, in steps SA102 to SA121, the same processes as steps S8202 to S8221 of the first timer interrupt process (FIG. 117) in the thirty-third embodiment are executed. If the determination in step SA107 is affirmative, or if the process in step SA121 is executed, the interrupt permission setting is set to permit the generation of the first timer interrupt process (FIG. 148) and the second timer interrupt process (FIG. 123). Is performed (step SA122).

According to the above configuration, while the processing at the start of supplying the operating power is being executed in the main processing (FIG. 147), the interrupt of the second timer interrupt processing (FIG. 123) is permitted, while the first timer interrupt processing is performed. Interrupts (Fig. 148) are not allowed. Accordingly, it is possible to execute the display control of the first to fourth notification display devices 201 to 204 by the second timer interrupt process (FIG. 123) even in the situation where the process at the start of supplying the operating power is being executed. On the other hand, the processing for controlling the progress of the game by the first timer interrupt processing (FIG. 148) can be prevented from being executed.

Further, the first timer interrupt process (FIG. 148) does not start by interrupting the second timer interrupt process (FIG. 123), and the second timer interrupt process (FIG. 123) becomes the first timer interrupt process (FIG. 148). It does not start by interrupting it. This makes it possible to prevent the timer interrupt processing from being activated again.

<Forty-third embodiment>
In this embodiment, the configuration for displaying the base value on the first to fourth notification display devices 201 to 204 is different from that of the 35th embodiment. The configuration different from that of the 35th embodiment will be described below. The description of the same configuration as the thirty-fifth embodiment is basically omitted.

In the present embodiment as well, similar to the 35th embodiment, the normal counter area 231 is provided in the work area 223 for non-specific control. Similar to the fifteenth embodiment, the normal counter area 231 has a normal general prize winning counter 231a, a normal special electric prize winning counter 231b, a normal first operating counter 231c, a normal second operating counter 231d and A normal out counter 231e is provided. In a situation where neither the open/close execution mode due to the big hit result nor the high frequency support mode is present, when one game ball enters the general winning opening 31, the value of the normal general winning counter 231a is incremented by 1, When one game ball enters the prize winning device 32, the value of the special electric prize winning counter 231b for normal is incremented by 1, and when one game ball enters the first operating port 33, it is for normal use. The value of the first operation counter 231c of 1 is added, and when one game ball enters the second operation port 34, the value of the normal second operation counter 231d is added by 1, and the value is added to the outlet 24a. When one game ball enters, the value of the normal out counter 231e is incremented by 1. Then, when the values of the various counters 231a to 231e of the normal counter area 231 are K91 to K95 in a situation where neither the open/close execution mode based on the jackpot result nor the high frequency support mode is used, the base values are as follows.
Base value: total payout number of game balls (K91 x "number of prize balls for winning in general prize hole 31" + K92 x "number of prize balls for winning in special electric prize winning device 32" + K93 x "to first operating port 33" Ratio of the total number of game balls discharged from the game area PA (K91+K92+K93+K94+K95)+K94דnumber of prize balls for winning in the second operation port 34”)/K94.

In the work area 223 for non-specific control, a calculation result storage area 234 is provided in addition to the normal counter area 231. Similar to the thirty-fifth embodiment, the calculation result storage area 234 serves as a storage area for storing the base value information, as a current status area 311, a first history area 312, a second history area 313, and a second history area 313. 3 history area 314 is provided (see FIG. 126). The current area 311 stores the latest base value calculated by the result calculation process (FIG. 149). In the first history area 312, the final base value in the previous calculation period is stored. In the second history area 313, the final base value in the calculation period two times before is stored. The final base value in the calculation period three times before is stored in the third history area 314.

FIG. 149 is a flowchart showing the result calculation processing executed by the main CPU 63 in this embodiment. The management process (step S8920) in the first timer interrupt process (FIG. 133) corresponds to the non-specific control in step S3803, like the management process (FIG. 70) in the fifteenth embodiment. Read the program for management execution processing. Then, in this management execution process (FIG. 71), the check process is executed in step S3908 as in the fifteenth embodiment. In this check processing, the result calculation processing is executed and the display processing (FIG. 150) described later is executed. Further, the processing of step SA201 to step SA217 in the result calculation processing is executed using the non-specific control program and non-specific control data in the main CPU 63.

First, the base value calculation process is executed (step SA201). In the arithmetic processing, the base value is calculated using the values of the various counters 231a to 231e in the normal counter area 231 as in the 35th embodiment. Here, in the present embodiment, the calculation of the base value is not completed in one processing cycle of the result calculation processing, but is completed by executing the processing cycle of the result calculation processing a plurality of predetermined times.

Specifically, in a predetermined number of times of the result calculation processing in which the calculation of the base value is newly started, in step SA201, the values of the various counters 231a to 231e in the normal counter area 231 are set to K91 to K95. In this case, K91דthe number of prize balls for winning in the general winning opening 31”, K92דnumber of prize balls for winning in the special electric prize winning device 32”, and K93דwinning for the first operating opening 33” The number of prize balls", K94 x "the number of prize balls for winning in the second operation port 34", and the total number of game balls discharged from the game area PA (K91+K92+K93+K94+K95) are calculated, and the respective calculation results are calculated. Is stored in the in-calculation storage area provided in the work area 223 for non-specific control. After that, in step SA201 of the result calculation processing of the processing number one time after the predetermined processing number, the total payout number of the game balls (K91×) is utilized by using the various information stored in the calculation-in-progress storage area. "Number of prize balls for winning in the general prize opening 31" + K92 x "Number of prize balls for winning in the special electric prize winning device 32" + K93 x "Number of prize balls for winning in the first operating port 33" + K94 x "Second operation The number of prize balls for winning in the mouth 34") is calculated, and the calculation result is stored in the above-mentioned calculation storage area. Then, in step SA201 of the result calculation processing of the processing times two times after the predetermined processing times, the base value is calculated using various information stored in the calculation-in-progress storage area.

That is, in the present embodiment, it is necessary to execute the result calculation processing three times in order to calculate one base value. In this case, since the result calculation process is called and executed in the first timer interrupt process (FIG. 133), it is executed every time the first interrupt period (specifically, 4 milliseconds) elapses. Become. Therefore, one base value is calculated in a cycle of about 12 milliseconds. However, the cycle in which one base value is calculated is not limited to this, and may be a cycle shorter than the 12-millisecond cycle or a cycle longer than the 12-millisecond cycle.

As described above, by adopting a configuration in which one base value is calculated by executing the result operation processing a plurality of times, it is possible to reduce the processing load for calculating the base value. In particular, since the result calculation process is executed as a process corresponding to the non-specific control, not only the process of reading the program for the non-specific control and the data for the non-specific control but also the specific control for executing the result calculation process. It is necessary to save the information of the various registers of the main CPU 63 used in the process corresponding to. In this case, by reducing the processing load for calculating the base value, it is possible to reduce the processing load of the result calculation process, and as a result, the processing load for executing the process corresponding to the non-specific control. Can be reduced.

Even if the result calculation process is executed multiple times to calculate one base value, each piece of information during the calculation of the base value in each process of the result calculation process is a work for non-specific control. Written in area 223. As a result, the main CPU 63 used in the process corresponding to the non-specific control is performed as the process corresponding to the specific control is executed between one processing cycle of the result calculation processing and the next processing cycle. Even if the information in the various registers is erased, it is possible to store and hold each piece of information during the calculation of the base value.

Even in a configuration in which the processing times of the result calculation processing for calculating one base value are executed a plurality of times, the normal counter area 231 is used in the first processing time of the result calculation processing for calculating the new base value. All the values of the various counters 231a to 231e are extracted, and the extracted values are used to calculate the base value of the calculation times. As a result, even if the values of the various counters 231a to 231e in the normal counter area 231 are changed while the one base value is being calculated, the one base value is prevented while being unaffected by the change of the value. Can be calculated.

After the base value calculation processing is executed in step SA201, it is determined whether or not the calculation of one base value is completed in the result calculation processing of this processing time (step SA202). When the calculation of one base value is not completed (step SA202: NO), the current value area 311 of the calculation result storage area 234 is not overwritten with the base value by not executing the processing of steps SA203 to SA205.

When the calculation of one base value is completed (step SA202: YES), the calculated base value is overwritten in the current area 311 (step SA203). After that, it is determined whether or not "1" is set in the shift trigger flag provided in the work area 223 for non-specific control (step SA204). In the present embodiment, the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) in a situation that is neither the open/close execution mode due to the jackpot result nor the high frequency support mode. When the calculation of the new base value is completed after the shift reference number (specifically, 60000) is reached, the data shift process (step SA216) in the calculation result storage area 234 is executed. In this data shift process, the information stored in the current state area 311, the first history area 312, the second history area 313, and the third history area 314 in the calculation result storage area 234 is changed from the second history area 313 to the third history area. After shifting in the order of 314, first history area 312→second history area 313, current area 311→first history area 312, the current area 311 is cleared to “0”. The shift trigger flag is a flag for the main CPU 63 to specify that the situation is after the total number of game balls has reached the shift reference number and before the data shift process is executed.

When "1" is set in the shift trigger flag (step SA204: YES), "1" is set in the shift completion flag provided in the work area 223 for non-specific control (step SA205). The calculation completion flag at the time of shift is a flag for the main CPU 63 to specify that the calculation of one base value is completed after the total number of game balls reaches the shift reference number.

If a negative determination is made in step SA202, a negative determination is made in step SA204, or the process of step SA205 is executed, "1" is set to the management start flag provided in the work area 223 for non-specific control. It is determined whether or not it is set (step SA206). If "1" is not set in the management start flag (step SA206: NO), the management pre-processing is executed (step SA207). In the pre-management start process, the processes of steps S8604 to S8608 of the result calculation process (FIG. 130) in the 35th embodiment are executed.

When the management start flag is set to "1" (step SA206: YES), it is determined whether the shift trigger flag in the work area 223 for non-specific control is set to "1" (step SA208). .. When "1" is not set in the shift trigger flag (step SA208: NO), the total number is calculated by summing the values of the various counters 231a to 231e in the normal counter area 231 (step SA209). Then, it is determined whether or not the calculated total number is not less than the shift reference number of 60000 (step SA210).

When a positive determination is made in step SA210, "1" is set to the shift trigger flag in the work area 223 for non-specific control (step SA211). Further, "1" is set to the pre-shift display flag provided in the work area 223 for non-specific control (step SA212). The pre-shift display flag mainly indicates that the pre-shift display corresponding to the fact that the total number of game balls has reached the shift reference number should be started on the first to fourth notification display devices 201 to 204. This is a flag for specifying by the side CPU 63.

When the shift trigger flag is set to "1" and a positive determination is made in step SA208, it is determined whether or not the calculation completion flag at the time of shift in the work area 223 for non-specific control is set to "1". Yes (step SA213). The calculation completion flag at the time of shift is set to "1" when the calculation of one base value is completed after the total number of game balls has reached the shift reference number as already described. When a positive determination is made in step SA213, the shift trigger flag in the work area 223 for non-specific control is cleared to "0" (step SA214). Further, the operation completion flag at the time of shift in the work area 223 for non-specific control is cleared to "0" (step SA215).

Then, the data shift process is executed (step SA216). In the data shift process, the information stored in the current state area 311, the first history area 312, the second history area 313, and the third history area 314 in the calculation result storage area 234 is changed from the second history area 313 to the third history area 314. , The first history area 312→the second history area 313, the current area 311→the first history area 312, and then the current area 311 is cleared to “0”. As a result, the final base value in the calculation period two times before is stored in the third history area 314 as the final base value in the calculation period three times before, and the final base value in the calculation period one time before. Is stored in the second history area 313 as the final base value in the calculation period two times before, and the base value calculated after the total number of the game balls reaches the shift reference number in the current calculation period is once. It is stored in the first history area 312 as the final base value in the previous calculation period. Further, the current area 311 is in a state where no base value is stored. In the data shift processing, the LDIR instruction is used when the above information shift is performed. In the LDIR instruction, the information stored in the storage area is shifted (copied) to the storage area by designating the address of the storage area of the information and the address of the storage area of the information. Becomes After that, the counters 231a to 231e in the normal counter area 231 are all cleared to "0" (step SA217).

FIG. 150 is a flowchart showing the display processing in this embodiment executed by the main CPU 63. The processing of steps SA301 to SA320 in the display processing is executed using the non-specific control program and non-specific control data in the main CPU 63.

First, it is determined whether or not "1" is set in the management start flag in the work area 223 for non-specific control (step SA301). When a negative determination is made in step SA301, the base value is read from the current area 311 and the decimal point is the first decimal place in the read base value, as in step S8714 of the display process (FIG. 131) in the thirty-fifth embodiment. And the calculation result data corresponding to the second decimal point number are set in the display target setting area 276 (step SA302). By transmitting the display data corresponding to the calculation result data to the display IC 266, the first decimal place number in the base value of the current area 311 is displayed on the third notification display device 203, and the base of the current area 311 is displayed. The second digit of the decimal point in the value is displayed on the fourth annunciator display device 204. With the above configuration, when the management start flag is not set to "1", the base value in the past calculation period is not notified, and only the base value calculated in the current calculation period is notified. To be done. Note that the display contents of the first to fourth notification display devices 201 to 204 when the base value is notified in a situation where the management start flag is not set to "1" are the same as those in the 35th embodiment. ..

When a positive determination is made in step SA301, the value of the switching timing counter provided in the work area 223 for non-specific control is decremented by 1 (step SA303). The switching timing counter determines the timing of switching the display content of the first to fourth notification display devices 201 to 204 in the situation where the base values are displayed on the first to fourth notification display devices 201 to 204. It is a counter for specifying in.

In the present embodiment, the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) in a situation that is neither the open/close execution mode due to the jackpot result nor the high frequency support mode. When the shift reference number is not reached, the notification of the base value stored in each of the current area 311, the first history area 312, the second history area 313, and the third history area 314 is displayed continuously (specifically, Is executed for 5 seconds), and the interval non-display is performed for the interval period (specifically 1 sec.) in order to notify that the switching of the base value to be notified occurs between the notifications of the base values. Seconds). Specifically, as the interval non-display, all the display segments 321 to 324 in the first to fourth notification display devices 201 to 204 are turned off, so that the first to fourth notification display devices 201 to 201 are displayed. 204 is hidden. The non-display for the interval is performed before the base value to be notified is switched in a predetermined order of the current area 311→the first history area 312→the second history area 313→the third history area 314. It is possible for the manager of the game hall to clearly recognize that the target base value is switched.

In a situation where the total number of game balls has reached the shift reference number, the corresponding pre-shift display is performed on the first to fourth notification display devices 201 to 204. Specifically, as the pre-shift display, “A.” is displayed on each of the first to fourth notification display devices 201 to 204. The display content of "A." is the display content that is not displayed on the first to fourth notification display devices 201 to 204 in both the display continuation period of the display corresponding to the base value and the interval period in which the interval is not displayed. is there. As a result, the entire display contents of the first to fourth notification display devices 201 to 204 in the situation where the pre-shift display is performed are the display continuation period of the display corresponding to the base value and the interval period in which the interval is not displayed. Can have different display contents. Therefore, when the manager of the game hall confirms that the pre-shift display is being performed on the first to fourth display devices 201 to 204, the total number of the game balls has reached the shift reference number. This makes it possible to understand that the base value is being shifted.

The display contents of the pre-shift display are the display contents of the first to fourth notification display devices 201 to 204 in the situation in which the check display is being performed, and the first in the situation in which "1" is not set in the pre-management start flag. Display contents of the first to fourth notification display devices 201 to 204, display contents of the first to fourth notification display devices 201 to 204 in a situation where the setting confirmation process (FIG. 136) is being executed, and setting value update It is also different from the display contents of the first to fourth notification display devices 201 to 204 in the situation where the process (FIG. 137) is being executed. From this point as well, the manager of the game hall confirms that the pre-shift display is being performed on the first to fourth notification display devices 201 to 204, so that the total number of the game balls is the shift reference number. It becomes possible to understand that the base value is being shifted by reaching the value of.

The execution period of the pre-shift display is set to be longer than the interval period (specifically, 1 second) in which the interval non-display is performed. The execution period of the pre-shift display is set to be longer than the display continuation period (specifically, 5 seconds) of the display corresponding to the base value. Specifically, the execution period of the pre-shift display is set to 8 seconds. Note that the present invention is not limited to this, and the execution period of the pre-shift display may be longer than the interval period and equal to or less than the display continuation period of the display corresponding to the base value, or may be equal to or less than the interval period. .. However, in order for the manager of the game hall to clearly recognize that the pre-shift display is being performed, it is preferable that the execution period of the pre-shift display is set to be longer than the interval period.

As already described, in order to complete the calculation of one base value, the result operation processing (FIG. 149) needs to be executed a plurality of times. Specifically, the cycle for calculating one base value is It has a cycle of 12 milliseconds. Further, when the total number of game balls reaches the shift reference number, the data shift processing (step SA216) in which the information of the base value is shifted among the various areas 311 to 314 of the calculation result storage area 234 is set to the shift reference number. It is executed after one base value is newly calculated after reaching. In this case, the execution period of the pre-shift display is longer than the longest period required to complete the data shift process (step SA216) when the total number of game balls reaches the shift reference number. It is set. As a result, the new calculation of one base value and the data shift processing of the base value (step SA216) are completed in the situation where the pre-shift display is being performed on the first to fourth notification display devices 201 to 204. Is possible.

Returning to the description of the display process (FIG. 150), when the process of step SA303 is executed, it is determined whether or not the value of the switching timing counter after subtracting 1 is “0” to display the base value. It is determined whether or not the current measurement target period has elapsed among the continuation period, the interval period in which the interval non-display is performed, and the pre-shift display execution period (step SA304). When an affirmative determination is made in step SA304, it is a situation in which pre-shift display should be started by determining whether or not "1" is set in the pre-shift display flag in the work area 223 for non-specific control. It is determined whether or not (step SA305). When a negative determination is made in step SA305, it is determined whether "1" is set in the interval flag provided in the work area 223 for non-specific control (step SA306). The interval flag is a flag for the main CPU 63 to specify whether or not the non-display for interval should be started.

When a negative determination is made in step SA306, it means that the target of which the notification should be started in the first to fourth notification display devices 201 to 204 at this switching timing is the base value. In this case, the value of the display target counter provided in the work area 223 for non-specific control is incremented by 1 (step SA307). When the value of the display target counter after adding 1 exceeds the maximum value of "3" (step SA308: YES), the value of the display target counter is cleared to "0" (step SA309).

The display target counter is the first to fourth notification displays among the base values stored in the current state area 311, the first history area 312, the second history area 313, and the third history area 314 in the calculation result storage area 234. This is a counter for the main CPU 63 to specify the base value to be notified in the devices 201 to 204. Specifically, when the value of the display target counter is “0”, the base value stored in the current area 311 becomes the notification target, and when the value of the display target counter is “1”, the first history area When the base value stored in 312 is the notification target and the value of the display target counter is “2”, the base value stored in the second history area 313 is the notification target and the value of the display target counter is “3”. , The base value stored in the third history area 314 becomes the notification target.

When a negative determination is made in step SA308 or when the process of step SA309 is executed, the base timing is displayed on the switching timing counter of the work area 223 for non-specific control as a value corresponding to the next switching timing. A value corresponding to the display continuation period (specifically, 5 seconds) is set (step SA310). Then, "1" is set to the interval flag in the work area 223 for non-specific control (step SA311). As a result, if "1" is not set in the pre-shift display flag in the work area 223 for non-specific control by the next switching timing, the interval non-display will be performed when the next switching timing comes. It will be displayed.

After that, the processing for setting the display data corresponding to the base value that is the current notification target in the display target setting area 276 provided in the work area 223 for non-specific control is executed. Specifically, similar to step S8708 of the display process (FIG. 131) in the thirty-fifth embodiment, the display type data corresponding to the value of the display target counter is set in the display target setting area 276 (step SA312). .. The display type data includes display data for causing the first notification display device 201 to perform a display indicating that the notification target of the first to fourth notification display devices 201 to 204 is the base value, and the notification target base. A display indicating which of the current area 311, the first history area 312, the second history area 313 and the third history area 314 the value corresponds to in the calculation result storage area 234 is displayed on the second notification display device 202. And display data to be executed.

After that, as in step S8709 of the display process (FIG. 131) in the thirty-fifth embodiment, the current state area 311, the first history area 312, the second history area 313, and the third history area 314 in the calculation result storage area 234 are displayed. A base value is read from the area corresponding to the value of the display target counter, and calculation result data corresponding to the decimal point first digit and the decimal point second digit in the read base value are displayed in the display target setting area 276. Is set (step SA313). The calculation result data includes display data for causing the third notification display device 203 to perform a display corresponding to the first decimal place number in the notification target base value, and the second decimal point number in the notification target base value. And display data for causing the fourth notification display device 204 to perform a display corresponding to.

By setting the display data including the display type data and the calculation result data in the display target setting area 276, the display data is displayed by the second timer interrupt process (FIG. 134) as in the thirty-fifth embodiment. The display corresponding to the display data is displayed on the first to fourth notification display devices 201 to 204. That is, when the base value of the current area 311 is the notification target, the display as shown in FIG. 127A is displayed on the first to fourth notification display devices 201 to 204 as an example. When the base value of the history area 312 is the notification target, the display as shown in FIG. 127(b) is displayed on the first to fourth notification display devices 201 to 204 as an example, and the second history area is displayed. When the base value of 313 is the notification target, the display as shown in FIG. 127C is displayed on the first to fourth notification display devices 201 to 204 as an example, and the third history area 314 is displayed. When the base value is the notification target, the display as shown in FIG. 127D is displayed on the first to fourth notification display devices 201 to 204 as an example.

When a positive determination is made in step SA306 because the interval flag in the work area 223 for non-specific control is set to "1", the switching timing of this time is displayed on the first to fourth notification display devices 201 to 204. Means that the target for which the notification should be started is the interval non-display. In this case, the interval setting process is executed (step SA314). In the setting process, a value corresponding to the interval period (specifically, 1 second) is set in the switching timing counter of the work area 223 for non-specific control as a value corresponding to the next switching timing. After that, the interval flag in the work area 223 for non-specific control is cleared to "0" (step SA315). As a result, when "1" is not set in the pre-shift display flag in the work area 223 for non-specific control by the next switching timing, the base value of the base value is set when the next switching timing comes. It will be displayed.

After that, the interval data is set in the display target setting area 276 provided in the work area 223 for non-specific control (step SA316). The interval data is data for causing the first to fourth notification display devices 201 to 204 to perform interval non-display, and specifically, all of the first to fourth notification display devices 201 to 204. This is data for turning off the display segments 321 to 324. By setting the interval data as the display data in the display target setting area 276, the interval data is transmitted to the display IC 266 by the second timer interrupt process (FIG. 134), and the first to fourth notification display devices 201 to 201 All of 204 are in a non-display state. The manager of the game hall, who has confirmed that the first to fourth notification display devices 201 to 204 are in the non-display state, can recognize that it is the interval period.

When a positive determination is made in step SA305 because the pre-shift display flag in the work area 223 for non-specific control is set to "1", the first to fourth notification display devices 201 to 204 indicate the current time. This means that the target to be notified when the switching timing is triggered is the pre-shift display. In this case, the pre-shift display period setting process is executed (step SA317). In the setting process, a value corresponding to the execution period of the pre-shift display (specifically, 8 seconds) is set in the switching timing counter of the work area 223 for non-specific control as a value corresponding to the next switching timing.

After that, the interval flag in the work area 223 for non-specific control is cleared to "0" and the pre-shift display flag in the work area 223 for non-specific control is cleared to "0" (step SA318). The maximum value "3" is set in the display target counter in the work area 223 (step SA319). When the execution period of the pre-shift display has elapsed by clearing the interval flag to “0”, the next notification target becomes the base value. Then, by setting the maximum value to the display target counter, if a negative determination is made in step SA306 to notify the base value, the display target counter after adding 1 to the value of the display target counter in step SA307 Value exceeds the maximum value, a positive determination is made in step SA308, and the value of the display target counter is cleared to "0". Accordingly, when the execution period of the pre-shift display has elapsed, the next notification target becomes the base value, and the base value becomes the base value of the current area 311 of the calculation result storage area 234.

That is, when the pre-shift display is performed, whether the notification target before the pre-shift display is the base value or the interval non-display is started from the notification of the base value. As a result, when the pre-shift display is completed, the base value can be confirmed without waiting for the interval period to elapse. In addition, the base value that is the last notification target before the pre-shift display is displayed in any of the current state area 311, the first history area 312, the second history area 313, and the third history area 314 of the calculation result storage area 234. Even if there is, when the pre-shift display is completed, the notification is started from the base value of the current area 311. This makes it possible to return the notification order of the base values in the current area 311, the first history area 312, the second history area 313, and the third history area 314 to the first notification order, and immediately after the base value shift occurs. It is possible to make it easy for the manager of the game hall to recognize that

Thereafter, the pre-shift display data is set in the display target setting area 276 provided in the work area 223 for non-specific control (step SA320). The pre-shift display data is data for causing the first to fourth notification display devices 201 to 204 to perform the pre-shift display. Specifically, in each of the first to fourth notification display devices 201 to 204, " It is data for displaying "A.". By setting the pre-shift display data as the display data in the display target setting area 276, the pre-shift display data is transmitted to the display IC 266 in the second timer interrupt process (FIG. 134), and the first to fourth notifications are made. “A.” is displayed on each of the display devices 201 to 204. The manager of the game hall, who confirms that the pre-shift display is being performed on the first to fourth notification display devices 201 to 204, can recognize that it is the execution period of the pre-shift display. ..

Next, referring to the time chart of FIG. 151, in a situation where the management start flag is set to “1”, the base values of the various areas 311 to 314 are notified on the first to fourth notification display devices 201 to 204. The situation will be explained. FIG. 151( a) shows a period in which the base value stored in the current area 311 is notified by the first to fourth notification display devices 201-204, and FIG. 151( b) is stored in the first history area 312. 151(c) shows the base values stored in the second history area 313 for the first to fourth notifications. 151(d) shows the base value stored in the third history area 314 in the first to fourth notification display devices 201-204. 151(e) shows a period during which interval non-display is performed on the first to fourth notification display devices 201 to 204, and FIG. 151(f) shows the first to fourth notification display devices. 201 to 204 show a period during which the pre-shift display is performed, and FIG. 151(g) shows a case where neither the open/close execution mode according to the jackpot result nor the high frequency support mode has occurred since the base value calculation period was newly started The timing when the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) reaches the shift reference number (specifically, 60000) is shown.

At timing t1, as shown in FIG. 151(a), the notification of the base value stored in the current area 311 is started on the first to fourth notification display devices 201 to 204. At the time of this notification, as shown in FIG. 127(a), a display indicating that the base value is the notification target is displayed on the first notification display device 201, and is stored in the current area 311 on the second notification display device 202. The display indicating that the base value is the notification target is displayed, and the display corresponding to the base value stored in the current area 311 is displayed on the third notification display device 203 and the fourth notification display device 204.

After that, when the display continuation period elapses from the timing of t1 at the timing of t2, the notification of the base value stored in the current area 311 is finished as shown in FIG. 151(a), and shown in FIG. 151(e). Thus, the non-display for intervals is started on the first to fourth notification display devices 201 to 204. This non-display for interval is ended as shown in FIG. 151(e) at the timing of t3 which is the timing when the interval period has elapsed from the timing of t2.

At the timing of t3, as shown in FIG. 151(b), the notification of the base value stored in the first history area 312 is started on the first to fourth notification display devices 201 to 204. In this notification, as shown in FIG. 127(b), a display indicating that the base value is the notification target is displayed on the first notification display device 201, and the second notification display device 202 displays on the first history area 312. A display indicating that the stored base value is a notification target is performed, and a display corresponding to the base value stored in the first history area 312 is displayed on the third notification display device 203 and the fourth notification display device 204. Done.

After that, when the display continuation period elapses from the timing of t3 at the timing of t4, the notification of the base value stored in the first history area 312 is finished as shown in FIG. 151(b), and the notification of the base value is finished. As shown in, the interval non-display is started on the first to fourth notification display devices 201 to 204. This non-display for interval is ended as shown in FIG. 151(e) at the timing of t5, which is the timing when the interval period has elapsed from the timing of t4.

At the timing of t5, the notification of the base value stored in the second history area 313 is started on the first to fourth notification display devices 201 to 204 as shown in FIG. 151(c). In this notification, as shown in FIG. 127(c), a display indicating that the base value is the notification target is displayed on the first notification display device 201, and the second notification display device 202 displays in the second history area 313. A display indicating that the stored base value is a notification target is performed, and a display corresponding to the base value stored in the second history area 313 is displayed on the third notification display device 203 and the fourth notification display device 204. Done.

After that, when the display continuation period elapses from the timing of t5 at the timing of t6, the notification of the base value stored in the second history area 313 is finished as shown in FIG. 151(c), and FIG. 151(e). As shown in, the interval non-display is started on the first to fourth notification display devices 201 to 204. This interval non-display is ended as shown in FIG. 151(e) at the timing of t7, which is the timing when the interval period has elapsed from the timing of t6.

At the timing of t7, as shown in FIG. 151(d), the notification of the base value stored in the third history area 314 is started on the first to fourth notification display devices 201 to 204. In this notification, as shown in FIG. 127(d), a display indicating that the base value is the notification target is displayed on the first notification display device 201, and the second notification display device 202 displays in the third history area 314. A display indicating that the stored base value is a notification target is performed, and a display corresponding to the base value stored in the third history area 314 is displayed on the third notification display device 203 and the fourth notification display device 204. Done.

After that, when the display continuation period elapses from the timing of t7 at the timing of t8, the notification of the base value stored in the third history area 314 is ended as shown in FIG. As shown in, the interval non-display is started on the first to fourth notification display devices 201 to 204. This non-display for interval is ended as shown in FIG. 151(e) at the timing of t9, which is the timing when the interval period has elapsed from the timing of t8.

After that, similarly to the timing of t1 to the timing of t2 from the timing of t9 to the timing of t10, the display corresponding to the base value stored in the current area 311 as shown in FIG. No. 4 notification display devices 201 to 204 are performed, and the interval non-display is performed as shown in FIG. 151(e) in the same manner as the timing of t2 to the timing of t3 from timing t10 to timing t11. This is performed on the first to fourth notification display devices 201 to 204. Then, similarly to the timing of t3, the display corresponding to the base value stored in the first history area 312 is displayed at the timing of t11 as shown in FIG. 151(b). Started at.

After that, at the timing of t12 which is the timing during which the display corresponding to the base value stored in the first history area 312 is being performed, the base value calculation period is newly added as shown in FIG. 151(g). The total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) is shifted in a situation where neither the open/close execution mode due to the jackpot result nor the high frequency support mode has been started since the start. The reference number (specifically, 60,000) is reached. However, at the timing of t12, since the display continuation period has not elapsed since the display corresponding to the base value of the first history area 312 was started at the timing of t11, as shown in FIG. The display corresponding to the base value of the one history area 312 is continued. Thereby, even if the timing when the total number of the game balls reaches the shift reference number is arbitrary, the display of the current notification target on the first to fourth notification display devices 201 to 204 is performed as planned. It is possible to start the pre-shift display on the first to fourth notification display devices 201 to 204 after performing the operation for the period.

After that, when the display continuation period elapses from the timing of t11 at the timing of t13, the notification of the base value stored in the first history area 312 is ended as illustrated in FIG. 151(b), and the notification of the base value illustrated in FIG. 151(f) is completed. As shown in, the pre-shift display is started on the first to fourth notification display devices 201 to 204. Even if the total number of game balls reaches the shift reference number while other base values are being notified, if the display continuation continuation for the notification of the base value has elapsed, before the shift. The display is started on the first to fourth notification display devices 201 to 204. Further, even if the total number of game balls reaches the shift reference number while the non-display for the interval is being performed, the pre-shift display is displayed when the interval period for the non-display for the interval has elapsed. The first to fourth notification display devices 201 to 204 are started.

After that, at the timing of t14, the execution period of the pre-shift display elapses from the timing of t13, the pre-shift display is ended as shown in FIG. 151(f), and the current area 311 is shown as shown in FIG. 151(a). The notification of the base value stored in is started by the first to fourth notification display devices 201 to 204. That is, even if the notification target when the pre-shift display is started is the base value of the first history area 312, when the pre-shift display is completed, it corresponds to the first notification order in the base value notification order. The notification is started from the base value of the current area 311.

After that, when the display continuation period elapses from the timing of t14 at the timing of t15, the notification of the base value stored in the current area 311 is finished as shown in FIG. 151(a), and then shown in FIG. 151(e). Thus, the non-display for intervals is started on the first to fourth notification display devices 201 to 204. This interval non-display is ended as shown in FIG. 151(e) at the timing of t16, which is the timing when the interval period has passed from the timing of t15, and as shown in FIG. 151(b), the base of the first history area 312 is displayed. The display corresponding to the value is started on the first to fourth notification display devices 201 to 204.

According to this embodiment described in detail above, the following excellent effects are exhibited.

The base values stored in the current state area 311, the first history area 312, the second history area 313, and the third history area 314 of the calculation result storage area 234 are sequentially displayed on the first to fourth notification display devices 201 to 204. To be done. Thereby, it becomes possible to individually notify the respective base values corresponding to different periods while suppressing the number of the first to fourth notification display devices 201 to 204. Further, since each base value is displayed in a predetermined order, the manager of the game hall can easily understand the type of the base value to be displayed.

The display order of the base values is determined in association with each of the current state area 311, the first history area 312, the second history area 313, and the third history area 314 in the calculation result storage area 234. This makes it possible to simplify the processing configuration for specifying the type of the base value to be displayed when the base value is newly displayed.

Before the situation in which one base value is displayed is changed to the situation in which the next base value is displayed, the first to fourth notification display devices 201 to 204 are in the interval non-display state. This allows the manager of the game hall to clearly understand that the type of the base value to be displayed has been switched.

In the configuration in which the base values are sequentially displayed on the first to fourth notification display devices 201 to 204, in either the open/close execution mode or the high frequency support mode depending on the jackpot result after the base value calculation period is newly started. When the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) reaches the shift reference number (specifically, 60000) in the absence of the first condition, the first -Pre-shift display is performed on the fourth notification display devices 201 to 204. Thereby, it becomes possible to notify that the total number of the game balls has reached the shift reference number by using the first to fourth notification display devices 201 to 204.

When the total number of game balls has reached the shift reference number, the base value stored in the current result area 311, the first history area 312, the second history area 313, and the third history area 314 in the calculation result storage area 234. Is shifted to a storage area on the rear side of the storage order, various counters 231a to 231e in the normal counter area 231 are cleared to "0", and calculation of a base value for a new calculation period is started. Therefore, when the total number of the game balls reaches the shift reference number, the content of the base value notification on the first to fourth notification display devices 201 to 204 is changed. In this case, when the total number of the game balls reaches the shift reference number, the notification of the base value is restarted after the pre-shift display is performed, so that the total number of the game balls reaches the shift reference number. It is possible for the manager of the game hall to recognize that the notification contents of the base value are changed in response to this.

When the total number of game balls reaches the shift reference number while the base value is being displayed, the pre-shift display is started after the display continuation period of the display of the base value has elapsed. This makes it possible to start the pre-shift display while not disturbing the already-displayed base value.

In the configuration in which the plurality of base values stored in the calculation result storage area 234 are sequentially displayed in the predetermined display order, after the pre-shift display is performed, the base values in the first order in the predetermined display order are displayed. As a result, when the total number of game balls has reached the shift reference number, it is possible to check again from the base value of the first order in the predetermined display order.

In the configuration for calculating the base value in the result calculation process (FIG. 149), the result calculation process is executed a plurality of times from the start of calculation of one base value until the calculation of the base value is completed. As a result, it is possible to reduce the processing load for executing the result calculation process, as compared with the configuration in which the calculation of the base value is completed in one result calculation process.

When the total number of game balls has reached the shift reference number, the base value data shift processing (step SA216) is executed after the base value is newly derived at the timing when the shift reference number is reached. When the total number of the game balls has reached the shift reference number, the pre-shift display is performed on the first to fourth notification display devices 201 to 204. As a result, in a situation where the base value is newly derived and the data shift process of the base value is being performed, it becomes possible to perform pre-shift display on the first to fourth notification display devices 201 to 204. It is possible to prevent the previous display of the base value from being continued even though the reference number has been reached.

In addition, since the base value calculation period is started, the total number of game balls discharged from the game area PA (that is, supplied to the game area PA in a situation where neither the open/close execution mode due to the jackpot result nor the high-frequency support mode is used). Until the total number of game balls reaches the initial reference number (specifically 6000), as in the 35th embodiment, when the base value of the current area 311 is displayed, the first to fourth values are displayed. It is also possible to adopt a configuration in which the calculation initial display is performed on the notification display devices 201 to 204.

In addition, when the total number of the game balls reaches the shift reference number (specifically, 60000) in a state where the first to fourth notification display devices 201 to 204 are not displayed for the interval, it is immediately shifted. The total number of game balls has reached the shift reference number (specifically, 60000) in the situation where the previous display is started and the base value is displayed on the first to fourth notification display devices 201 to 204. In this case, the pre-shift display may be started when the display continuation period of the display of the base value has elapsed. As a result, the pre-shift display can be started early while preventing the already-displayed base value from being terminated halfway.

The display contents of the pre-shift display are not limited to those described above, and the display contents on at least a part of the first to fourth notification display devices 201 to 204 can be displayed in other situations. However, the entire display content of the first to fourth notification display devices 201 to 204 may be display content that is not displayed in other situations. Further, when the pre-shift display is performed, at least one display segment 321 to 324 is turned on in each of the first to fourth notification display devices 201 to 204. For some of the 4 notification display devices 201 to 204, all the display segments 321 to 324 may be turned off. Further, when the pre-shift display is performed, the display content of the pre-shift display is not limited to the configuration in which it is maintained for the execution period of the pre-shift display. The configuration may be such that it blinks during the execution period of.

Further, the execution period of the pre-shift display is not limited to a fixed configuration. For example, a new base value is calculated after the total number of game balls reaches the shift reference number (specifically, 60000). The execution period of the pre-shift display may be changed according to the period required to complete the data shift process of the base value.

Further, when the total number of the game balls reaches the shift reference number, the last of the display laps of the respective base values being performed on the first to fourth notification display devices 201 to 204 at that time point. The configuration may be such that the pre-shift display is started after the display of the sequential base values (that is, the base values stored in the third history area 314) is completed. As a result, after the display cycle of each base value is completed, it is possible to start a new display cycle of each base value via the pre-shift display.

Further, when the total number of game balls reaches the shift reference number, the calculation of the base value is started using the various counters 231a to 231e in the normal counter area 231 at that time, and the calculation of the base value is started. The data shift process (step SA216) may be performed when the process is completed. In this case, it is possible to accurately calculate the base value at the timing when the total number of game balls reaches the shift reference number.

Further, in the interval period, instead of performing the non-display for the interval, at least a part of the first to fourth notification display devices 201 to 204 performs a predetermined display and the first to fourth notification display. The entire display of the devices 201 to 204 may be configured to perform an interval display having display content different from display content that may occur in a situation where the base value is notified. For example, in each of the first to fourth notification display devices 201 to 204, only the central display segments 321 to 324 may be in a lighting state so that “−” is displayed. The display of "-" may be displayed on a part of the display devices 201 to 204 for 4 notification and the remaining display devices may be in the non-display state.

Further, the interval period may not be set. In this case, when the display continuation period has elapsed for one base value, the display of the base value to be displayed in the next order is started on the first to fourth notification display devices 201 to 204. Become.

<44th Embodiment>
In this embodiment, the start timing of the pre-shift display is different from that in the 43rd embodiment. Hereinafter, a configuration different from that of the forty-third embodiment will be described. The description of the same configuration as that of the forty-third embodiment is basically omitted.

The start timing of the pre-shift display in this embodiment will be described with reference to the time chart of FIG. FIG. 152(a) shows a period in which the base value stored in the current area 311 is notified by the first to fourth notification display devices 201-204, and FIG. 152(b) is stored in the first history area 312. 152(c) shows the base value stored in the second history area 313 for the first to fourth notifications. 152D shows the period notified by the display devices 201-204, and FIG. 152D shows the base values stored in the third history area 314 notified by the first-fourth display devices 201-204. 152(e) shows a period in which interval non-display is performed on the first to fourth notification display devices 201 to 204, and FIG. 152(f) shows a first to fourth notification display device. 201 to 204 show a period during which the pre-shift display is performed, and FIG. 152(g) shows a case where neither the open/close execution mode according to the jackpot result nor the high frequency support mode has occurred since the base value calculation period was newly started. The timing when the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) has reached the shift reference number (specifically, 60000) is shown.

At the timing of t1 to t11, the display continuation period is displayed on the first to fourth notification display devices 201 to 204, similarly to the time charts of FIGS. 151(a) to 151(g) in the forty-third embodiment. The display corresponding to the base value and the execution of the non-display for the interval in the interval period are repeated, and the display corresponding to the base value is the current status area 311 of the calculation result storage area 234→the first history area 312→the second area. The history area 313 is repeated in the order of the third history area 314. Then, at the timing of t11, as shown in FIG. 152(b), the display corresponding to the base value stored in the first history area 312 is started on the first to fourth notification display devices 201 to 204.

After that, at the timing t12, which is the timing during which the display corresponding to the base value stored in the first history area 312 is being performed, the base value calculation period is newly added as shown in FIG. 152(g). The total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) is shifted in a situation where neither the open/close execution mode due to the jackpot result nor the high frequency support mode has been started since the start. The reference number (specifically, 60,000) is reached. In this case, at the timing of t12, although the display continuation period has not elapsed since the display corresponding to the base value of the first history area 312 was started at the timing of t11, as shown in FIG. 152(b). The notification of the base value stored in the first history area 312 is terminated, and the pre-shift display is started on the first to fourth notification display devices 201 to 204 as shown in FIG. 152(f).

Even if the total number of the game balls reaches the shift reference number while the other base values are being notified, the pre-shift display is the first to fourth notification display devices 201 at that timing. It starts at ~204. Further, even when the total number of the game balls reaches the shift reference number while the non-display for interval is being performed, the pre-shift display is the first to fourth notification display devices 201 to 204 at that timing. Started at.

After that, when the execution period of the pre-shift display elapses from the timing of t12 at the timing of t13, the pre-shift display is ended as shown in FIG. 152(f), and the current area 311 is shown as shown in FIG. The notification of the base value stored in is started by the first to fourth notification display devices 201 to 204. That is, even if the notification target when the pre-shift display is started is the base value of the first history area 312, when the pre-shift display is completed, it corresponds to the first notification order in the base value notification order. The notification is started from the base value of the current area 311.

After that, when the display continuation period elapses from the timing of t13 at the timing of t14, the notification of the base value stored in the current area 311 is finished as shown in FIG. 152(a), and shown in FIG. 152(e). Thus, the non-display for intervals is started on the first to fourth notification display devices 201 to 204. This interval non-display is ended as shown in FIG. 152(e) at the timing of t15, which is the timing when the interval period has elapsed from the timing of t14, and as shown in FIG. 152(b), the base of the first history area 312 is displayed. The display corresponding to the value is started on the first to fourth notification display devices 201 to 204.

According to the above configuration, since the base value calculation period is newly started, the total number of game balls discharged from the game area PA (that is, the game) in a situation where neither the open/close execution mode by the jackpot result nor the high frequency support mode is present. When the total number of game balls supplied to the area PA has reached the shift reference number (specifically, 60000), before the shift on the first to fourth notification display devices 201 to 204 at that timing. The display will start. As a result, the pre-shift display can be started early, and it is possible to notify early that the total number of game balls has reached the shift reference number.

<45th Embodiment>
In this embodiment, the processing configuration of the main processing executed by the main CPU 63 is different from that in the 35th embodiment. The configuration different from that of the 35th embodiment will be described below. The description of the same configuration as the thirty-fifth embodiment is basically omitted.

FIG. 153 is a flowchart showing the main processing executed by the main CPU 63 in this embodiment. Note that the processing of steps SA401 to SA425 in the main processing is executed using the program for specific control and the data for specific control in the main CPU 63.

First, power-on initialization processing is executed (step SA401). In the power-on initialization process, for example, a predetermined wait time (specifically, 1 second) elapses after the main process is started, and the process waits without proceeding to the next process. In the predetermined period for this weight, the operation start and initial setting of the symbol display device 41 are completed. Also, access to the main RAM 65 is permitted.

Then, the internal function register setting process is executed (step SA402). In the internal function register setting process, as in the 35th embodiment, the interrupt period of the first timer interrupt process (FIG. 133), which is a process that is activated by periodically interrupting the main process, is set to the first interrupt period. (Specifically, 4 ms), and the interrupt period of the second timer interrupt process (FIG. 134), which is a process that is periodically interrupted and activated with respect to the main process, is set from the first interrupt period. Is set to the second interrupt cycle (specifically, 2 milliseconds) which is a short cycle.

That is, in this embodiment, as in the 35th embodiment, the first timer interrupt processing (FIG. 133) and the second timer interrupt processing (FIG. 134) are performed so that the interrupt cycle becomes relatively short as the timer interrupt processing. And exist. Both the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134) are activated by interrupting the main process. The second timer interrupt process (FIG. 134) is activated by interrupting the first timer interrupt process (FIG. 133). On the other hand, the first timer interrupt process (FIG. 133) does not start by interrupting the second timer interrupt process (FIG. 134). In addition, when both the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134) are not executed, and when both the first interrupt cycle and the second interrupt cycle have passed, those cycles The second timer interrupt processing (FIG. 134) is started first regardless of the lapsed order of the above. In this respect, it can be said that the second timer interrupt process (FIG. 134) is a process that is activated prior to the first timer interrupt process (FIG. 133). However, the configuration is not limited to this, and the first timer interrupt process (FIG. 133) may be activated prior to the second timer interrupt process (FIG. 134).

In the internal function register setting process, the first interrupt period of the first timer interrupt process (FIG. 133) is set in a predetermined register of the main CPU 63, and the second interrupt period of the second timer interrupt process (FIG. 134) is set. It is set in a specific register of the side CPU 63. Further, in the internal function register setting process, in addition to the setting of the first and second interrupt cycles, the setting process of the numerical range of various counters such as the numerical range of the hit random number counter C1 is executed.

After that, "1" is set to the in-start-up processing flag provided in the work area 221 for specific control (step SA403). As in the 35th embodiment, the start-up processing flag is among the various processes set in the first timer interrupt process (FIG. 133) even if the first timer interrupt process (FIG. 133) is activated. While the power outage monitoring, the processing for updating various counters and the illegality monitoring are executed, the first timer interrupt processing (FIG. 133) should be terminated without executing the processing for advancing the game. This is a flag for specifying by the main CPU 63.

As for the start-up processing in progress flag, the processing at the time of starting the supply of the operating power (step SA401 to step SA418) is started in the main processing (FIG. 153) and the interruption permission (step SA404) is started as in the 35th embodiment. "1" is set before the operation is performed, and "0" is cleared before the processing at the start of the supply of the operating power is finished and the residual processing (step SA422 to step SA425) is started. In this case, similarly to the 35th embodiment, in the first timer interrupt processing (FIG. 133), when the start-up processing flag is set to "1", the processing of steps S8907 to S8920 is not executed. By doing so, it becomes possible to prevent the process for advancing the game from being executed in the situation where the process at the start of supplying the operating power (step SA401 to step SA418) is being executed. On the other hand, as described above, in the first timer interrupt processing (FIG. 133), even if the start-up processing flag is set to "1", by executing the processing of steps S8901 to S8905, the operating power is reduced. The power failure monitoring is performed even when the process (step SA401 to step SA418) at the start of the supply of is performed, and the winning random number counter C1, the jackpot type counter C2, the reach random number counter C3, and the random number initial value counter are also performed. Update of CINI is executed, and further fraud detection is executed.

Particularly, even when the start-up processing flag is set to "1", the power failure information storage processing (step S8901) is executed to start the operation power supply start processing (steps SA401 to SA418). Even if a power failure occurs in the situation where (1) is being executed, it is possible to execute the power failure process for it. In the power failure process, as in the thirty-fifth embodiment, the power failure flag provided in the specific control work area 221 is set to "1", the checksum is calculated, and the calculated checksum is used for the specific control. Since the data is stored in the work area 221 of No. 1, it is possible to prevent the occurrence of an abnormality in the main RAM 65 when the supply of operating power is restarted. As a result, when a power failure occurs during the setting confirmation process (step SA415) or the set value update process (step SA418), the fact that a power failure has occurred during these setting-related processes is supplied to the next operating power. It is possible to specify at the start.

By the way, in the situation where the setting confirmation process (step SA415) or the set value update process (step SA418) is being executed, both the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134) are performed. Interrupts are not prohibited and can be interrupted at any timing. In this case, the first timer interrupt process (FIG. 133) or the second timer interrupt process (FIG. 134) is executed in the main process (FIG. 153) including the setting confirmation process (step SA415) and the setting value update process (step SA418). When the program is interrupted and activated, the information on the return address of the main process (FIG. 153) for returning after the timer interrupt process which is the activation target is completed is saved in the stack area 222 for specific control. Information of various registers of the main CPU 63 immediately before the timer interrupt processing is activated is saved in the stack area 222 for specific control. Then, when the timer interrupt process that is the activation target ends, the process returns to the process of the main process (FIG. 153) corresponding to the information of the return address saved in the stack area 222 for specific control, and The information saved in the stack area 222 for specific control is restored to various registers of the main CPU 63.

After setting the start-up processing flag to "1" in step SA403, interrupt permission is set (step SA404). As a result, the first timer interrupt process (FIG. 133) is interrupted and activated in the first interrupt cycle, and the second timer interrupt process (FIG. 134) is interrupted and activated in the second interrupt period. However, since "1" is set in the startup processing flag in step SA403, even if the first timer interrupt processing (FIG. 133) is started, various processing of the first timer interrupt processing (FIG. 133) is performed. Out of the above, processing for performing power failure monitoring, updating various counters, and fraud monitoring is executed, while the processing for advancing the game is not executed, and the first timer interrupt processing (FIG. 133) is ended. ..

Then, it is determined whether or not the reset button 68c has been pressed (step SA405). That is, it is determined whether or not the power of the pachinko machine 10 is turned on while the reset button 68c is being pressed and the supply of operating power to the main CPU 63 is started. Here, in the present embodiment, as in the 35th embodiment, the main control device 60 is provided with the setting key insertion portion 68a and the reset button 68c, but is not provided with the update button 68b. Further, the main control device 60 is provided with not the first to third notification display devices 69a to 69c but the first to fourth notification display devices 201 to 204 as in the eleventh embodiment.

When the reset button 68c has not been pressed (step SA405: NO), it is determined whether or not "1" is set in the power failure flag provided in the work area 221 for specific control (step SA406). When the power failure information storage processing (step S8901) of the first timer interrupt processing (FIG. 133) executes the power failure processing, the power failure flag is set to "1". The power outage flag is a flag for the main CPU 63 to specify whether or not the power outage process was appropriately performed at the previous power off time.

When the power failure flag is set to "1" (step SA406: YES), checksums are calculated for the specific control work area 221 and the specific control stack area 222 (step SA407). The method of calculating the checksum is the same as in the 33rd embodiment. After that, the specific control work area 221 and the specific control work area 221 which are calculated and stored in the specific control work area 221 in the power failure process executed immediately before the supply of the operating power to the main CPU 63 is stopped. The checksum for the stack area 222 is read, and the read checksum is compared with the checksum calculated in step SA407 (step SA408). Then, it is determined whether or not the checksums match (step SA409).

When a negative determination is made in step SA406 or step SA409, that is, when the power failure flag is not set to "1" or the checksums do not match, the game stop flag provided in the work area 221 for specific control Is set to "1" (step SA410). When the game stop flag is set to "1", the processes of steps S8901 to S8905 are executed in the first timer interrupt process (FIG. 133), while the positive determination is made in step S8906 to steps S8907 to step. The process of S8920 is not executed. As a result, if the power failure flag is not set to "1" because the power failure process was not properly performed at the previous power shutdown, or the specific control work area 221 and the specific control stack area 222 are set. If the checksums do not match for at least one of the above due to the information storage state changing since the last power-off, the processing for power failure monitoring, updating various counters, and unauthorized monitoring is executed. On the other hand, the processing for advancing the game is not executed.

After that, an abnormal command indicating that an abnormality has occurred with respect to the power failure flag or the checksum at the start of supplying the operating power is transmitted to the voice light emission control device 81 (step SA411). Upon receiving the abnormal command, the sound emission control device 81 causes the display light emitting unit 53 to emit light in a manner corresponding to the information abnormality at the time of starting the supply of the operating power, and the speaker unit 54 "Please change the setting." Is output. Moreover, the character image "Please change the setting." is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are ended when the supply of operating power to the pachinko machine 10 is stopped. However, even if the supply of the operating power to the pachinko machine 10 is temporarily stopped, the above notification is given when the supply of the operating power to the pachinko machine 10 is restarted until the setting value update processing (step SA418) is executed. The configuration may be continued.

When the power failure flag is set to "1" and the checksum is normal (step SA406 and step SA409: YES), "1" is set to the setting update display flag provided in the work area 221 for specific control. It is determined whether it has been done (step SA412). The setting update display flag is a flag for the main CPU 63 to specify that the setting value update processing (step SA418) is being executed as in the 35th embodiment, and the setting update display flag is "1". When is set, the display indicating that the setting value is being updated and the setting value being updated are displayed on the first to fourth notification display devices 201 to 204. The setting update display flag is a flag that is set to "1" when the setting value updating process (step SA418) is started and is cleared to "0" when the setting value updating process (step SA418) is ended. In the situation where the set value update process (step SA418) is not executed, basically, the state where the setting update display flag is set to "1" is not set. However, when the supply of operating power to the main CPU 63 is stopped in the situation where the set value updating process (step SA418) is being executed, and then the supply of operating power to the main CPU 63 is started. In, the setting update display flag is set to "1". When the setting update display flag is set to "1", the RAM clearing process (step SA416) is executed, or the setting update display flag is cleared to "0" in the setting value updating process (step SA418). It is maintained until it is executed.

When a negative determination is made in step SA412 because "1" is not set in the setting update display flag, it is determined whether the setting key insertion portion 68a is turned on by using the setting key (step SA413). ). When the setting key insertion unit 68a is turned on by using the setting key (step SA413: YES), the setting confirmation process is executed (step SA415). Even when the setting key insertion unit 68a is not turned on by using the setting key (step SA413: NO), the setting confirmation display flag provided in the work area 221 for specific control is set to "1". If is set (step SA414: YES), the setting confirmation process is executed (step SA415). The setting confirmation process will be described later.

The setting confirmation display flag is a flag for the main CPU 63 to specify that the processing for setting confirmation (step SA415) is being executed as in the 35th embodiment, and the setting confirmation display flag is "1". When is set, a display indicating that the setting value is being confirmed and a display indicating the currently set setting value are displayed on the first to fourth notification display devices 201 to 204. Be seen. The setting confirmation display flag is a flag that is set to "1" when the setting confirmation process (step SA415) is started and is cleared to "0" when the setting confirmation process (step SA415) is ended. In a situation where the setting confirmation process (step SA415) is not executed, basically, the setting confirmation display flag is not set to "1". However, when the supply of the operating power to the main CPU 63 is stopped in the situation where the setting confirmation process (step SA415) is being executed, and then the supply of the operating power to the main CPU 63 is started. In the setting confirmation display flag, "1" is set. When the setting confirmation display flag is set to "1", the RAM clearing process (step SA416) is executed, or the setting confirmation display flag is cleared to "0" in the setting confirmation process (step SA415). It is maintained until it is executed.

When the reset button 68c is pressed (step SA405: YES), the RAM clear process is executed (step SA416). In the RAM clearing process, in the specific control work area 221, the specific control is performed except for an area (specifically, a setting reference area 341 described later) in which information of a setting value indicating the setting state of the pachinko machine 10 is set. The work area 221 for use is cleared to "0" and the initial setting is executed. As a result, the area indicating whether or not the winning/winning lottery mode is the high-probability mode is cleared to "0". The mode is a low probability mode. In addition, the game times are not being executed, the opening/closing execution mode is not being executed, and the general-purpose display unit 38a is not being variably displayed, and the general electric accessory 34a is in the closed state. It becomes a situation. Further, since the hold storage area 65a and the universal electric power reserve area 65c provided in the work area 221 for specific control are also cleared to "0", the reserved information for the special figure display section 37a is deleted and the general figure display section is deleted. The hold information for 38a is deleted. Further, the setting update display flag and the setting confirmation display flag provided in the specific control work area 221 are cleared to "0". Further, the setting update area 342, which will be described later, provided in the specific control work area 221 is cleared to “0”. In the RAM clearing process, the stack area 222 for specific control is cleared to "0" and the initial setting is executed. In the RAM clearing process, various registers of the main CPU 63 are cleared to "0" and then the initial setting is executed. In this initial setting, processing similar to the internal function register setting processing in step SA402 is executed. The process for clearing “0” and the process for initial setting are not executed for the work area 223 for non-specific control and the stack area 224 for non-specific control.

Then, it is determined whether or not the setting key inserting section 68a is turned on by using the setting key (step SA417). When the ON operation is performed (step SA417: YES), the set value updating process is executed (step SA418). The setting value update process will be described later.

When the process of step SA411 is executed, a negative determination is made in step SA414, the process of step SA415 is executed, a negative determination is made in step SA417, or the process of step SA418 is executed, specific control Information corresponding to the initial check period (specifically, 5 seconds) is set in the checking counter provided in the work area 221 (step SA419). The value set in the checking counter is decremented by 1 each time the second timer interrupt process (FIG. 134) is activated, as in the 35th embodiment. When the value of 1 or more is set in the checking counter, the check display is continued on the first to fourth notification display devices 201 to 204 as in the 35th embodiment.

According to the above configuration, when the supply of the operating power to the main CPU 63 is started, the residual processing is performed after the processing at the start of the supply of the operating power (step SA401 to step SA418) is completed in the main CPU 63. Before (Step SA422 to Step SA425) are started, the initial check period is started. Accordingly, since it is not necessary to control the initial check period in the situation where the processing at the start of supplying the operating power is executed, the processing load in the situation where the processing at the start of supplying the operating power is executed is reduced. It becomes possible.

Further, while the setting confirmation process (step SA415) and the setting value update process (step SA418) are executed as the process at the start of the supply of the operating power, the process at the start of the supply of the operating power is performed during the initial check period. It is started after finishing. Accordingly, even if the check display is performed on the first to fourth notification display devices 201 to 204 during the initial check period, the set values are displayed using the first to fourth notification display devices 201 to 204. It becomes possible not to affect.

After that, the start-up processing flag in the work area 221 for specific control is cleared to "0" (step SA420). When the first timer interrupt process (FIG. 133) is started by clearing the start-up processing flag “0”, a negative determination is made in step S8906, and thus not only the processes of steps S8901 to S8905 The processing of steps S8907 to S8920 will be executed, and the state where the processing for advancing the game is not executed is released. In step SA420, the power failure flag in the specific control work area 221 is also cleared to "0".

After that, a return command is transmitted to the voice emission control device 81 (step SA421). The content of the information included in the return command and the processing content of the voice emission control device 81 when the return command is received are the same as those in step S7920 of the main processing (FIG. 114) in the 33rd embodiment. ..

After that, the process proceeds to the residual process of steps SA422 to SA425. In other words, the main CPU 63 is configured to periodically execute the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134), but between the one timer interrupt process and the next timer interrupt process. There will be some residual time. This remaining time will vary depending on the processing completion time of each timer interrupt processing, but the remaining processing of steps SA422 to SA425 is repeatedly executed by utilizing this irregular time. In this respect, it can be said that the residual process of steps SA422 to SA425 is an irregular process that is irregularly executed. In steps SA422 to SA425, the same processes as steps S113 to S116 of the main process (FIG. 9) in the first embodiment are executed.

Next, the configuration related to the set values in this embodiment will be described. FIG. 154 is an explanatory diagram for explaining the contents of a storage area for setting values provided in the specific control work area 221.

As shown in FIG. 154, the work area 221 for specific control is provided with a setting reference area 341 and a setting update area 342. The setting reference area 341 is a storage area in which information for specifying the current setting value of the pachinko machine 10 by the main CPU 63 is stored. In step S503 of the special figure variation start process (FIG. 13), the current setting value of the pachinko machine 10 is specified based on the information stored in the setting reference area 341, and the win/fail table corresponding to the specified setting value is read. Then, in step S504, the read/write table is used to execute the determination processing. Further, in the situation where the setting confirmation display flag in the specific control work area 221 is set to "1", the display of the setting value corresponding to the information stored in the setting reference area 341 is the fourth notification display. This is performed by the device 204.

Numerical information is stored in the setting reference area 341 as setting value information. Specifically, when the setting reference area 341 stores numerical information of “1”, the current setting value of the pachinko machine 10 is “setting 1”. When the numerical information of “2” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 2”. When the numerical information of “3” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 3”. When the numerical information of “4” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 4”. When the numerical information of “5” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 5”. When the numerical information of “6” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 6”.

The setting update area 342 stores information on the setting value being updated in the setting value updating process (step SA418). That is, in the set value update process (step SA418), the information of the set value to be selected is updated every time the reset button 68c is pressed, but the setting stored in the setting reference area 341 is updated at this time. The setting value information stored in the setting updating area 342 is changed without changing the value information. As a result, it becomes possible to update the set value while storing and holding the information of the set value that was set before the start of the set value updating process (step SA418). When the setting value updating process (step SA418) is completed, the setting reference information 341 is overwritten with the setting value information stored in the setting updating area 342 at that time. As a result, the set value obtained as a result of the update in the set value updating process (step SA418) is set as the set value of the current pachinko machine 10. Further, when the setting update display flag in the work area 221 for specific control is set to "1", the display of the setting value corresponding to the information stored in the setting update area 342 is the fourth notification display. This is performed by the device 204.

Numerical information is stored in the setting update area 342 as information on the set value. Specifically, when the numerical value information “1” is stored in the setting update area 342, the set value of the update target (selection target or change target) is “setting 1”. When the numerical information of “2” is stored in the setting update area 342, the setting value to be updated is “setting 2”. When the numerical information of “3” is stored in the setting update area 342, the setting value to be updated is “setting 3”. When the numerical information of "4" is stored in the setting update area 342, the setting value to be updated is "setting 4". When the numerical information of "5" is stored in the setting update area 342, the setting value to be updated is "setting 5". When the numerical information of “6” is stored in the setting update area 342, the setting value to be updated is “setting 6”.

FIG. 155 is a flowchart showing the setting confirmation process executed in step SA415 of the main process (FIG. 153). The processing of steps SA501 to SA504 in the setting confirmation processing is executed using the specific control program and specific control data in the main CPU 63.

On the condition that the setting confirmation display flag provided in the work area 221 for specific control is not set to "1" (step SA501: NO), the setting confirmation display flag is set to "1" (step SA502). .. When the setting confirmation display flag is set to "1", an affirmative determination is made in step S9005 of the second timer interrupt processing (FIG. 134). (Step S9006) is executed.

FIG. 156 is a flowchart showing the setting process for the fifth display data buffer 275 during the setting confirmation. Note that the processing of step SA601 to step SA603 in the setting processing is executed using the program for specific control and the data for specific control in the main CPU 63.

First, the display data of the setting value corresponding to the setting value information stored in the setting reference area 341 of the work area 221 for specific control is read (step SA601). Then, the read display data of the set value is set in the fifth display data buffer 275 in the specific control work area 221 as display data to be applied to the fourth notification display device 204 (step SA602). In addition, display data for causing the first to third notification display devices 201 to 203 to display that the setting value of the pachinko machine 10 is being confirmed is set in the fifth display data buffer 275. (Step SA603).

By executing the setting process for the fifth display data buffer 275 during the setting confirmation as described above, the displays corresponding to the display data set in the fifth display data buffer 275 in step SA603 are displayed as the first to the first. The third notification display devices 201 to 203 perform the display corresponding to the display data set in the fifth display data buffer 275 at step SA602 on the fourth notification display device 204. Thereby, as shown in the explanatory view of FIG. 124(b), for example, a display indicating that the setting value of the pachinko machine 10 is being confirmed and a display indicating the current setting value of the pachinko machine 10 are first. ~ The fourth notification display device 201 to 204.

Returning to the description of the setting confirmation process (FIG. 155), if a positive determination is made in step SA501 or the process of step SA502 is executed, the setting key insertion unit 68a uses the setting key to change from the ON state to the OFF state. It is determined whether the switching has been performed (step SA503). Specifically, it is determined whether the reception state of the signal received from the detection sensor that detects the state of the setting key insertion unit 68a has changed from the reception state corresponding to the ON state to the reception state corresponding to the OFF state. To do. Therefore, the OFF state is maintained not only when the setting key inserting section 68a is maintained in the ON state, but also when the setting confirmation process is started in a situation where the setting key inserting section 68a is in the OFF state. Also in this case, a negative determination is made in step SA503. When it is not specified that the setting key insertion unit 68a has switched from the ON state to the OFF state (step SA503: NO), the process of step SA503 is repeated.

When it is specified that the setting key insertion portion 68a has been switched from the ON state to the OFF state (step SA503: YES), the setting confirmation display flag in the specific control work area 221 is cleared to "0" (step SA504). As a result, a negative determination is made in step S9005 of the second timer interrupt processing (FIG. 134), so that the setting processing (step S9006) for the fifth display data buffer 275 during the setting confirmation is not executed. Therefore, on the first to fourth notification display devices 201 to 204, a display indicating that the current setting value of the pachinko machine 10 is being confirmed and a display indicating the current setting value of the pachinko machine 10 are displayed. The state to be performed is released.

As described above, when the power of the pachinko machine 10 is turned on while the setting key insertion portion 68a is turned on by the setting key without pressing the reset button 68c, the supply of operating power to the main CPU 63 is started. In the situation where the main process (FIG. 153) is started and the reset button 68c is not pressed and the setting key insertion part 68a is turned ON, the game can be advanced in the main process (FIG. 153). The setting confirmation processing (FIG. 155) is executed in a situation where the processing at the time of starting the supply of the operating power is being executed, which is the situation before the processing is performed. As a result, it becomes possible to confirm the set value in a situation where the game is not being played.

FIG. 157 is a flowchart showing the set value updating process executed in step SA418 of the main process (FIG. 153). Note that the processing of steps SA701 to SA710 in the setting value update processing is executed using the program for specific control and the data for specific control in the main CPU 63.

First, it is determined whether or not "1" is set in the setting update display flag provided in the work area 221 for specific control (step SA701). When "1" is not set in the setting update display flag (step SA701: NO), "1" is set in the setting update display flag (step SA702). After that, the setting value information stored in the setting reference area 341 in the specific control work area 221 is overwritten in the setting update area 342 in the specific control work area 221 (step SA703). As a result, the setting value information that was set when the supply of operating power was stopped last time is set in the setting update area 342.

On the other hand, the supply of the operating power is restarted after the supply of the operating power is stopped while the set value updating process is being executed, and the RAM clearing process (step SA416) of the main process (FIG. 153) is executed. If the setting update display flag is already set to "1" due to the start of the setting value update process (step SA701: YES), the process of step SA703 is not executed. In this case, the processing of step SA704 and the subsequent steps is executed in a state where the setting value information set in the setting update area 342 in the setting value update processing before the supply of the operating power is stopped is maintained. Become.

When the setting update display flag is set to "1", a positive determination is made in step S9003 of the second timer interrupt processing (FIG. 134), so that the setting processing for the fifth display data buffer 275 during the setting update is performed. (Step S9004) is executed.

FIG. 158 is a flowchart showing the setting processing for the fifth display data buffer 275 during the setting update. Note that the processing of step SA801 to step SA803 in the setting processing is executed by using the program for specific control and the data for specific control in the main CPU 63.

First, the display data of the setting value corresponding to the setting value information stored in the setting updating area 342 of the work area 221 for specific control is read (step SA801). Then, the read display data of the set value is set to the fifth display data buffer 275 in the work area 221 for specific control as display data to be applied to the fourth notification display device 204 (step SA802). In addition, display data for causing the first to third notification display devices 201 to 203 to display that the setting value of the pachinko machine 10 is being updated is set in the fifth display data buffer 275. (Step SA803).

By executing the setting process for the fifth display data buffer 275 during the setting update as described above, the display corresponding to the display data set in the fifth display data buffer 275 in step SA803 is changed from the first display to the first display. The third notification display devices 201 to 203 perform the display corresponding to the display data set in the fifth display data buffer 275 in step SA802 on the fourth notification display device 204. As a result, for example, as shown in the explanatory diagram of FIG. 124(a), a display indicating that the setting value of the pachinko machine 10 is being updated and the setting value selected as the update target of the pachinko machine 10 are displayed. The display is performed on the first to fourth notification display devices 201 to 204.

Returning to the description of the setting value update processing (FIG. 157), when the positive determination is made in step SA701 or the processing of step SA703 is executed, the setting value information stored in the setting update area 342 is from “1” to It is determined whether the value is "6" (step SA704). When it is not any of "1" to "6" (step SA704: NO), "1" is set in the setting update area 342 (step SA705). As a result, the setting value to be updated becomes “setting 1”.

When an affirmative judgment is made in step SA704 or the processing of step SA705 is executed, it is judged whether or not the setting key inserting section 68a has switched from the ON state to the OFF state by using the setting key (step SA706). Specifically, it is determined whether the reception state of the signal received from the detection sensor that detects the state of the setting key insertion unit 68a has changed from the reception state corresponding to the ON state to the reception state corresponding to the OFF state. To do. Therefore, the OFF state is maintained not only when the setting key inserting section 68a is maintained in the ON state, but also when the setting value updating process is started in the situation where the setting key inserting section 68a is in the OFF state. Also in this case, a negative determination is made in step SA706.

When a negative determination is made in step SA706, the value of the setting update area 342 is incremented by 1 on the condition that the reset button 68c is pressed (step SA707: YES) (step SA708). As a result, each time the reset button 68c is pressed once, the setting value is updated by one step. Further, when the reset button 68c is not pressed (step SA707: NO) or when the value of the setting update area 342 is incremented by 1, the process returns to step SA704, but the setting is updated in step SA704. When it is determined that the value of the use area 342 is 7 or more, “1” is set in the setting update area 342 in step SA705. As a result, when the reset button 68c is pressed once in the situation of "setting 6", the process returns to "setting 1".

When it is specified that the setting key insertion unit 68a has switched from the ON state to the OFF state (step SA706: YES), the setting reference area 341 is overwritten with the setting value information stored in the setting update area 342 ( Step SA709). As a result, the setting value information obtained as a result of the updating of the setting value this time is set in the setting reference area 341, and the setting value corresponding to the set information is set in the current pachinko machine 10. It becomes the set value.

Then, the setting update display flag in the specific control work area 221 is cleared to "0" (step SA710). As a result, a negative determination is made in step S9003 of the second timer interrupt process (FIG. 134), so that the setting process (step S9004) for the fifth display data buffer 275 is not executed during the setting update. Therefore, on the first to fourth notification display devices 201 to 204, the display indicating that the current set value of the pachinko machine 10 is being updated and the setting selected as the update target of the pachinko machine 10 are set. The state in which the value is displayed is canceled.

Based on not only performing the power ON operation of the pachinko machine 10 while pressing the reset button 68c as described above, but also performing the power ON operation of the pachinko machine 10 while further operating the setting key insertion portion 68a by the setting key. Not only the RAM clearing process (step SA416) but also the set value updating process (FIG. 157) is executed. In addition, as described above, the setting confirmation process (FIG. 155) is performed based on the power-on operation of the pachinko machine 10 while the setting key insertion portion 68a is turned on by the setting key without pressing the reset button 68c. Executed. As a result, it becomes possible to make the ON operation for the setting key insertion unit 68a common as the operation for executing the setting related processing regarding the setting value. Therefore, it becomes possible for the manager of the game hall to easily understand the operation content for generating the setting-related processing.

Further, when the power of the pachinko machine 10 is turned on while the setting key insertion portion 68a is turned on by the setting key, and the pressing operation of the reset button 68c is not added, the setting confirmation processing is executed and reset. When the pressing operation of the button 68c is added, the set value updating process is executed. As a result, it becomes possible to make the setting confirmation process and the setting value update process different from each other depending on whether or not the reset button 68c is pressed. Therefore, it becomes possible for the manager of the game hall to easily understand the operation content for executing the desired processing among the setting confirmation processing and the setting value updating processing. Further, by increasing the number of operations for executing the setting value updating process more than the setting confirming process, it becomes possible to make it particularly difficult to illegally perform the setting value updating process.

Next, when the power outage process is executed in the situation where the setting value update process (FIG. 157) or the setting confirmation process (FIG. 155) is being executed, the main process (Fig. The contents of the processing executed in (153) will be described with reference to the explanatory view of FIG. 159.

First, when the power outage process is executed in a situation in which neither the setting value update process (FIG. 157) nor the setting confirmation process (FIG. 155) is executed, the main process ( The contents of the processing executed in FIG. 153) will be described.

When the supply of operating power is resumed without the setting key insertion unit 68a being turned on and the reset button 68c being pressed (that is, when there is no operation), the RAM is used in the main process (FIG. 153). None of the clearing process (step SA416), the set value updating process (step SA418), and the setting confirmation process (step SA415) is executed. When the setting key insertion portion 68a is not turned on but the supply of operating power is resumed while the reset button 68c is being pressed (that is, when the "RAM clear operation" is performed), the main process (FIG. 153). Then, the RAM clearing process (step SA416) is executed, while the setting value updating process (step SA418) and the setting confirmation process (step SA415) are not executed. When the setting key insertion portion 68a is turned on and the reset button 68c is pressed and the supply of operating power is resumed (that is, when the "setting change operation" is performed), the RAM is used in the main process (FIG. 153). While the clearing process (step SA416) is executed and the setting value updating process (step SA418) is executed, the setting confirmation process (step SA415) is not executed. If the supply of operating power is resumed without pressing the reset button 68c while the setting key insertion portion 68a is turned on (that is, when the "setting check operation" is performed), the setting check process (step While SA415) is executed, the RAM clearing process (step SA416) and the set value updating process (step SA418) are not executed.

Next, when the power failure process is executed in the situation where the set value update process (step SA418) is being executed (that is, the condition where the setting update display flag is set to “1”), the subsequent supply of operating power The contents of the process executed in the main process (FIG. 153) when the process is restarted will be described.

When the supply of operating power is restarted in the state where the “RAM clear operation” is performed, the RAM clear process (step SA416) is executed in the main process (FIG. 153) while the set value update process (step SA418) and The setting confirmation process (step SA415) is not executed. In other words, even if the power outage process is executed in the situation where the set value update process (step SA418) is being executed, if the “RAM clear operation” is performed when the supply of the operating power is resumed after that, the set value is set. The RAM clearing process (step SA416) is executed without restarting the updating process (step SA418) and newly executing it. This makes it possible to prioritize the execution of only the RAM clear processing (step SA416) for the “RAM clear operation”. In this case, if the power outage process is executed before the process of step SA709 is executed in the set value update process (step SA418), the set value updated in the set value update process (step SA418) (that is, Since the information of the changed set value) is not set in the setting reference area 341, the set value that was set before the start of the set value updating process (step SA418) restarts the supply of the operating power. It will be used later. The setting update display flag is cleared to "0" by executing the RAM clearing process (step SA416).

When the supply of operating power is restarted in the situation where the “setting change operation” is performed, the RAM clearing process (step SA416) is executed and the setting value updating process (step SA418) is executed in the main process (FIG. 153). On the other hand, the setting confirmation process (step SA415) is not executed. That is, even if the power outage process is executed in the situation where the set value update process (step SA418) is being executed, the RAM is cleared when the “setting change operation” is performed when the supply of the operating power is resumed thereafter. After the process (step SA416) is executed, the set value update process (step SA418) is newly started.

When the RAM clearing process (step SA416) is executed, the setting update display flag in the specific control work area 221 is cleared to "0", as described above. Therefore, in the setting value updating process (FIG. 157), step SA701 is executed. By making a negative determination in, the setting value information stored in the setting reference area 341 is overwritten in the setting update area 342. Therefore, if the power failure process is executed before the process of step SA709 is executed in the set value update process (step SA418) before the supply of the operating power is stopped, the set value update process (step SA418). The information of the setting value updated in () is invalidated because it is not set in the setting reference area 341. In this case, in the set value updating process (step SA418) after the supply of the operating power is restarted, the setting that is set before the setting value updating process (step SA418) before the supply of the operating power is stopped is started. The set value is updated from the value.

If the supply of operating power is restarted in the situation of "no operation", or if the supply of operating power is restarted in the situation of "setting confirmation operation", the power failure flag and check are performed in the main process (Fig. 153). By making an affirmative decision in step SA412 on condition that no abnormality has occurred with respect to the thumb, the set value update processing (step SA418) is executed without the RAM clear processing (step SA416) being executed. If the RAM clearing process (step SA416) is not executed, the state in which the setting update display flag in the work area 221 for specific control is set to "1" is maintained, and therefore the step in the setting value updating process (FIG. 157) is performed. By making a positive determination in SA701, the information of the setting value of the setting update area 342 is maintained as it is. Therefore, the update of the set value is restarted from the set value that is being updated in the set value update process (step SA418) before the supply of the operating power is stopped. As a result, when the power failure process is executed in the middle of the set value updating process (step SA418) and the “RAM clear operation” is not performed when the supply of the operating power is resumed thereafter, the “setting Even if the "change operation" is not performed, the setting value update processing (step SA418) can be restarted.

In particular, it is assumed that the pachinko machine 10 is powered off by mistake while the set value updating process (step SA418) is being executed. In this case, the pachinko machine 10 is powered on immediately. It is possible that In this case, it is assumed that the power of the pachinko machine 10 is turned on without pressing the reset button 68c while the setting key insertion portion 68a is turned on, and then the "setting confirmation operation" is performed. In such a situation, the supply of operating power will be restarted. In such a situation, the set value updating process (step SA418) is executed as described above, and the set value updating process before the supply of the operating power is stopped in the set value updating process (step SA418) (step SA418). At, the update of the set value is restarted from the set value that is being updated. As a result, even if the above-mentioned event occurs, it is possible to restart the update of the set value without any problem.

Next, when the power failure processing is executed in the situation where the setting confirmation processing (step SA415) is being executed (that is, the setting confirmation display flag is set to "1"), the subsequent supply of operating power The contents of the process executed in the main process (FIG. 153) when the process is restarted will be described.

When the supply of operating power is restarted in the state where the “RAM clear operation” is performed, the RAM clear process (step SA416) is executed in the main process (FIG. 153) while the set value update process (step SA418) and The setting confirmation process (step SA415) is not executed. That is, even if the power failure process is executed while the setting confirmation process (step SA415) is being executed, the setting confirmation is performed when the "RAM clear operation" is performed when the supply of the operating power is resumed thereafter. The RAM clearing process (step SA416) is executed without newly executing the processing (step SA415). This makes it possible to prioritize the execution of only the RAM clear processing (step SA416) for the “RAM clear operation”. The setting confirmation display flag is cleared to "0" by executing the RAM clearing process (step SA416).

When the supply of operating power is restarted in the situation where the “setting change operation” is performed, the RAM clearing process (step SA416) is executed and the setting value updating process (step SA418) is executed in the main process (FIG. 153). On the other hand, the setting confirmation process (step SA415) is not executed. That is, even if the power outage process is executed in the situation where the setting confirmation process (step SA415) is executed, the setting confirmation is performed when the "setting change operation" is performed when the supply of the operating power is resumed thereafter. The setting value updating process (step SA418) is executed after the RAM clearing process (step SA416) is executed without newly executing the process (step SA415). This makes it possible to prioritize the execution of the RAM clearing process (step SA416) and the setting value updating process (step SA418) for the “setting change operation”. Even if the setting confirmation process (step SA415) is not executed in this way, the setting value to be updated is displayed on the fourth notification display device 204 by executing the setting value update process (step SA418). At the end of the set value update process (step SA418) that is displayed and set value information that is the update target at that time is set in the setting reference area 341, the manager of the game hall is in charge of the current pachinko machine. The set value of 10 can be confirmed. The setting confirmation display flag is cleared to "0" by executing the RAM clearing process (step SA416).

When the supply of operating power is restarted while the "setting confirmation operation" is performed, the main confirmation process (FIG. 153) is performed on condition that there is no abnormality in the power failure flag and checksum. SA 415) is executed. As a result, even if the power failure process is executed in the middle of the setting confirmation process (step SA415), it is possible to restart the confirmation of the set value by performing the "setting confirmation operation" when the supply of the operating power is resumed. Becomes

When the supply of operating power is restarted in the “no operation” situation, an affirmative decision is made in step SA414 on condition that no abnormality has occurred in the power failure flag and checksum in the main processing (FIG. 153). The setting confirmation process (step SA415) is executed even if the setting key insertion unit 68a is not turned on. As a result, even when the power failure process is executed in the middle of the setting confirmation process (step SA415) and the setting value is confirmed when the operation power supply is restarted after that, the operation is not performed. It becomes possible to restart.

Next, the end timing of the setting value update process (FIG. 157) and the setting confirmation process (FIG. 155) in relation to the operation state of the setting key insertion unit 68a will be described with reference to the time chart of FIG. FIG. 160(a) shows a period in which the power of the pachinko machine 10 is in an ON state, FIG. 160(b) shows a period in which the setting key insertion portion 68a is ON-operated, and FIG. 160(c) shows a setting. 160D shows the period during which the value update process (FIG. 157) is executed, FIG. 160D shows the period during which the setting confirmation process (FIG. 155) is executed, and FIG. Indicates the period of time that has been.

First, the case where each of the setting value update processing (FIG. 157) and the setting confirmation processing (FIG. 155) is executed in the normal flow will be described.

At the timing of t1, the setting key insertion portion 68a is turned on by using the setting key as shown in FIG. 160(b), and at the subsequent timing of t2, the power of the pachinko machine 10 is turned on as shown in FIG. 160(a). The operation is performed. In this case, the reset button 68c is also pressed. Therefore, at the timing of t3, the set value update processing (FIG. 157) is started as shown in FIG. 160(c). After that, at the timing of t4, as shown in FIG. 160(b), the setting key insertion portion 68a is changed from being turned on to being turned off. As a result, the set value updating process (FIG. 157) is completed as shown in FIG. 160(c).

Further, at the timing of t5, the setting key insertion portion 68a is turned on by using the setting key as shown in FIG. 160(b), and at the subsequent timing of t6, the power supply of the pachinko machine 10 is turned on as shown in FIG. 160(a). ON operation is performed. In this case, the reset button 68c is not pressed. Therefore, at the timing of t7, the setting confirmation process (FIG. 155) is started as shown in FIG. 160(d). After that, at the timing of t8, as shown in FIG. 160(b), the setting key insertion portion 68a is changed from the ON operation to the OFF operation. This completes the setting confirmation process (FIG. 155) as shown in FIG. 160(d).

Next, a case where the power failure process is executed during the execution of the set value updating process (FIG. 157) and the situation is “no operation” at the time of restarting the supply of the operating power will be described.

At time t9, the setting key insertion portion 68a is turned on by using the setting key as shown in FIG. 160(b), and at timing t10 thereafter, the power of the pachinko machine 10 is turned on as shown in FIG. 160(a). The operation is performed. In this case, the reset button 68c is also pressed. Therefore, at the timing of t11, the set value update processing (FIG. 157) is started as shown in FIG. 160(c). Then, as shown in FIG. 160(a), the power is turned off due to a power-off operation of the pachinko machine 10 or a sudden power failure of the commercial power supply at the timing of t12 during the execution of the set value updating process (FIG. 157). By entering the state, the power failure process is started as shown in FIG. 160(e). In this case, the set value updating process (FIG. 157) ends as shown in FIG. 160(c) at the timing t12, and the power failure process ends as shown in FIG. 160(e) at the timing t13.

After that, at the timing of t14, the setting key insertion portion 68a is turned off as shown in FIG. 160(b), and in that state, at the timing of t15, the power of the pachinko machine 10 is turned on as shown in FIG. 160(a). The ON operation is performed. In this case, the reset button 68c is not pressed. That is, the power-on operation of the pachinko machine 10 is performed in the state of “no operation”. However, when the power of the pachinko machine 10 is turned off last time, the power failure process is executed during the set value update process (FIG. 157). Therefore, at the timing of t16, the set value updating process (FIG. 157) is started as shown in FIG. 160(c). In this case, the set value update process (FIG. 157) is terminated when it is specified that the set key insertion unit 68a has been switched from the ON-operated state to the OFF-operated state. Even if the setting key insertion portion 68a is maintained in the OFF-operated state from the start timing of (157), the termination condition of the setting value update processing (FIG. 157) is not satisfied.

After that, as shown in FIG. 160(b), the setting key inserting section 68a is turned on by using the setting key at the timing of t17 which is in the middle of the execution of the set value updating process (FIG. 157), and then at t18. At a timing, as shown in FIG. 160(b), the setting key insertion portion 68a is changed from being turned on to being turned off. As a result, the set value updating process (FIG. 157) is completed as shown in FIG. 160(c).

Next, a case will be described in which the power failure process is performed during the setting confirmation process (FIG. 155) and the operation is not performed when the operating power supply is resumed.

At the timing of t19, the setting key insertion portion 68a is turned on by using the setting key as shown in FIG. 160(b), and at the timing of subsequent t20, the power of the pachinko machine 10 is turned on as shown in FIG. 160(a). The operation is performed. In this case, the reset button 68c is not pressed. Therefore, at the timing of t21, the setting confirmation process (FIG. 155) is started as shown in FIG. 160(d). Then, as shown in FIG. 160(a), the power is turned off due to a power-off operation of the pachinko machine 10 or a sudden power failure of the commercial power supply at the timing of t22 during the execution of the setting confirmation process (FIG. 155). By entering the state, the power failure process is started as shown in FIG. 160(e). In this case, the setting confirmation process (FIG. 155) ends as shown in FIG. 160(d) at the timing t22, and the power failure process ends as shown in FIG. 160(e) at the timing t23.

After that, at the timing of t24, the setting key insertion portion 68a is turned off as shown in FIG. 160(b), and in that state, at the timing of t25, the power of the pachinko machine 10 is turned off as shown in FIG. 160(a). The ON operation is performed. In this case, the reset button 68c is not pressed. That is, the power-on operation of the pachinko machine 10 is performed in the state of “no operation”. However, when the power of the pachinko machine 10 was turned off last time, the power failure process is executed during the setting confirmation process (FIG. 155). Therefore, at the timing of t26, the setting confirmation process (FIG. 155) is started as shown in FIG. 160(d). In this case, the setting confirmation process (FIG. 155) is terminated when it is specified that the setting key insertion portion 68a has been switched from the ON-operated state to the OFF-operated state. Even if the setting key insertion portion 68a is maintained in the OFF-operated state from the start timing of (155), the end condition of the setting confirmation process (FIG. 155) is not satisfied.

After that, as shown in FIG. 160(b), the setting key insertion portion 68a is turned on by using the setting key at the timing of t27 which is in the middle of the process for setting confirmation (FIG. 155), and then at t28. At a timing, as shown in FIG. 160( b ), the setting key insertion portion 68 a is changed from the ON operation to the OFF operation. This completes the setting confirmation process (FIG. 155) as shown in FIG. 160(d).

According to this embodiment described in detail above, the following excellent effects are exhibited.

In order to execute the set value updating process (FIG. 157), when the supply of the operating power is started, the setting key insertion portion 68a is turned on and the reset button 68c is pressed to perform the "setting." It is necessary to perform "change operation". As a result, it becomes possible to make it difficult to perform an act of illegally changing the set value. In this case, if the supply of the operating power is stopped in the situation where the set value updating process (FIG. 157) is being executed, the “setting change operation” is not performed when the supply of the operating power is resumed. However, the set value update process (FIG. 157) can be executed. As a result, it becomes possible to give priority to the execution of the setting value update processing (FIG. 157).

When the supply of operating power is stopped while the setting value updating process (Fig. 157) is being executed, a "setting confirmation operation" is performed to confirm the set value when the supply of operating power is resumed. In this case, the setting confirmation process (FIG. 155) is not executed, but the setting value update process (FIG. 157) is executed. This makes it possible to prioritize the change of the set value over the confirmation of the set value, so that the game will not be started even though the change of the set value to be used is not actually completed. It becomes possible.

In the situation where the set value update process (FIG. 157) is being executed, the set value selected as the update target is displayed on the first to fourth notification display devices 201 to 204. This makes it possible to change the setting value while grasping the setting value selected as the update target. In addition, by displaying the setting value selected as the update target in this way, the setting value updating process (see the figure) is performed despite the "setting confirmation operation" being performed when the supply of the operating power is restarted. Even if 157) is prioritized, it is possible to substantially confirm the set value.

In the situation where the set value update process (FIG. 157) is being executed, not only the display corresponding to the set value selected as the update target on the first to fourth notification display devices 201 to 204 but also the set value update process A display corresponding to the situation where (Fig. 157) is being executed is also displayed. As a result, even if the setting value updating process (FIG. 157) is started even though the “setting confirmation operation” is performed when the supply of the operating power is restarted, the setting value updating process (FIG. 157) is executed. It becomes easy for the manager of the game hall to know that the game has started.

When the operation power supply is stopped while the setting value update process (FIG. 157) is being executed, and when the operation power supply is then restarted, “no operation” or “setting confirmation operation” Is performed, the set value is changed from the set value that was selected before the supply of the operating power was stopped. This makes it possible to continue changing the set value from the set value selected before the supply of the operating power was stopped.

If the “setting change operation” is performed when the supply of the operating power is resumed after the supply of the operating power is stopped while the setting value updating process (FIG. 157) is being executed, The setting value is changed from the setting value to be used. This makes it possible to make the initial set value when changing the set value different depending on the operation content when the supply of operating power is restarted.

When the “RAM clear operation” is performed when the supply of the operating power is resumed even when the supply of the operating power is stopped while the set value updating process (FIG. 157) is being executed The set value update process (FIG. 157) is not executed. As a result, even when the supply of operating power is stopped in the situation where the set value updating process (FIG. 157) is being executed, it is not necessary to execute the set value updating process (FIG. 157) thereafter. By performing the “RAM clear operation” when the supply of the operating power is started, it becomes possible to prevent the set value updating process (FIG. 157) from being executed.

In order to execute the setting confirmation process (FIG. 155), it is necessary to perform the “setting confirmation operation” by turning on the setting key insertion portion 68a when the supply of operating power is started. .. As a result, it becomes possible to make it difficult to perform an act of illegally confirming the set value. In this case, when the supply of the operating power is stopped while the setting confirmation process (FIG. 155) is being executed, the “setting confirming operation” is not performed when the supply of the operating power is restarted. However, the setting confirmation process (FIG. 155) can be executed. This makes it possible to prioritize the execution of the setting confirmation process (FIG. 155).

When the “setting change operation” is performed when the supply of the operating power is resumed even when the supply of the operating power is stopped while the setting confirmation process (FIG. 155) is being executed, The setting value update processing (FIG. 157) is executed without executing the setting confirmation processing (FIG. 155). This makes it possible to prioritize the work of changing the set value over the work of confirming the set value.

The work area 221 for specific control is provided with a setting reference area 341 and a setting update area 342, and information corresponding to the setting value to be used is stored in the setting reference area 341, and the setting value update processing is performed. The information corresponding to the setting value being changed in the situation where (FIG. 157) is being executed is stored in the setting update area 342. As a result, while the setting reference information 341 stores and holds the information of the setting value set before the setting value updating process (FIG. 157) is started, the setting value update process (FIG. 157) sets the target of updating. It is possible to change the set value.

When the supply of operating power is stopped while the set value updating process (Fig. 157) is being executed, "no operation" or "setting confirmation operation" has been performed when restarting the supply of operating power thereafter. In this case, when the setting value is started to be changed from the setting value corresponding to the information stored in the setting update area 342, and when the “setting change operation” is performed at the time of restarting the supply of the operating power, The setting value may be changed from the setting value corresponding to the information stored in the setting reference area 341. This makes it possible to appropriately generate each of these situations.

In order to start the set value updating process (FIG. 157), it is necessary to turn on the setting key inserting section 68a using the setting key, so that the set value updating process (FIG. 157) is attempted to be illegally started. It becomes possible to make it difficult to perform an action. In this case, the set value updating process (FIG. 157) is not ended only by turning off the setting key inserting section 68a, but is turned off from the state where the setting key inserting section 68a is turned on. Will be finished. As a result, when the supply of the operating power is stopped while the setting value updating process (FIG. 157) is being executed, and “there is no operation” when the supply of the operating power is resumed after that, the setting key is inserted. Even if the setting value updating process (FIG. 157) is started in a state where the section 68a is in the OFF state, the setting value updating process (FIG. 157) is not immediately terminated, and the setting key insertion unit 68a is once turned ON. Since the set value update process (FIG. 157) is ended by further turning off after the operation, it is possible to end the set value update process (FIG. 157) at a timing preferable for the game hall manager.

In order to start the setting confirmation process (FIG. 155), it is necessary to turn on the setting key insertion unit 68a using the setting key, so that the setting confirmation process (FIG. 155) is attempted to be illegally started. It becomes possible to make it difficult to perform an action. In this case, the setting confirmation process (FIG. 155) is not ended only by turning off the setting key inserting section 68a, but is turned off from the state where the setting key inserting section 68a is turned on. Will be finished. As a result, when the supply of the operating power is stopped while the setting confirmation process (FIG. 155) is being executed, and when the supply of the operating power is resumed after that, the setting key is inserted. Even if the setting confirmation process (FIG. 155) is started in the state where the section 68a is in the OFF state, the setting confirmation process (FIG. 155) is not immediately terminated, and the setting key insertion section 68a is once turned ON. Since the setting confirmation process (FIG. 155) is ended by further turning it off after the operation, it is possible to end the setting confirmation process (FIG. 155) at a timing preferable for the game hall manager.

When the supply of the operating power to the main CPU 63 is started, the residual processing (step SA422 to step SA422) is performed after the process (step SA401 to step SA418) at the start of supplying the operating power is completed in the main CPU 63. The initial check period is started before SA425) is started. Accordingly, since it is not necessary to control the initial check period in the situation where the processing at the start of supplying the operating power is executed, the processing load in the situation where the processing at the start of supplying the operating power is executed is reduced. It becomes possible.

The setting confirmation process (FIG. 155) and the set value update process (FIG. 157) are executed as the process at the start of the supply of the operating power, whereas the process at the start of the supply of the operating power is completed during the initial check period. It will be started later. Accordingly, even if the check display is performed on the first to fourth notification display devices 201 to 204 during the initial check period, the set values are displayed using the first to fourth notification display devices 201 to 204. It becomes possible not to affect.

When the supply of operating power to the main CPU 63 is started, either the setting confirmation process (FIG. 155) or the set value update process (FIG. 157) is executed, and the setting confirmation process (FIG. 155) and the set value update processing (FIG. 157) are not executed, the check display is performed on the first to fourth notification display devices 201 to 204. This makes it possible to confirm whether or not the first to fourth notification display devices 201 to 204 are normal regardless of the situation when the supply of the operating power to the main CPU 63 is started.

In the main process (FIG. 153) of the main CPU 63, when either the setting confirmation process (FIG. 155) or the set value update process (FIG. 157) is executed, the setting confirmation process (FIG. 155) and the setting process are performed. This is a process that is commonly executed even when neither the value update process (FIG. 157) is executed, and whether the setting confirmation process (FIG. 155) or the set value update process (FIG. 157). When the execution is performed, the first to fourth notification display devices 201 to 204 are checked as the processing whose execution order is later than those of the setting confirmation processing (FIG. 155) and the setting value update processing (FIG. 157). The process to start the message display is set. In this way, the processing for starting the check display on the first to fourth notification display devices 201 to 204 is set as the common processing, so that the processing configuration is simplified and excellent as already described. It is possible to achieve the effect.

Even when the check display is being executed on the first to fourth notification display devices 201 to 204, the main CPU 63 can start the process for advancing the game. Thus, even if the check display is performed on the first to fourth notification display devices 201 to 204 after the setting confirmation process (FIG. 155) or the set value update process (FIG. 157) is executed, the game is played. It is possible to prevent the start timing of the processing for advancing from being delayed.

Note that if the operation power supply is stopped while the set value update processing (FIG. 157) is being performed and the operation power supply is resumed, “no operation” is performed, the set value update processing is performed. (FIG. 157) is not limited to the configuration started from the setting value being changed before the supply of the operating power is stopped, and is not limited to the setting value of the current use target stored in the setting reference area 341. The configuration may be started. Further, in the case where the operation power supply is stopped while the set value update processing (FIG. 157) is being executed and the operation power supply is resumed, if there is “no operation”, the RAM clear processing ( The configuration may be such that the setting value update process (FIG. 157) is executed after step SA416) is executed, and the RAM clear process (step SA416) is executed after the setting value update process (FIG. 157) is executed. May be

Further, when the supply of operating power is stopped while the setting value updating process (FIG. 157) is being executed, the setting value updating process ( 157) may not be executed. In this case, the setting value information stored in the setting reference area 341 may be overwritten in the setting update area 342 at the start of the next setting value update process (FIG. 157).

Further, when the operation power supply is stopped while the setting confirmation process (FIG. 155) is being executed, when the operation power supply is resumed, the setting confirmation process ( 155) may not be executed.

Further, in the case where the supply of the operating power is stopped in the situation where the set value updating process (FIG. 157) is being executed and the “RAM clear operation” is performed when the supply of the operating power is resumed, The setting value update process (FIG. 157) may be performed after the RAM clear process (step SA416) is performed. In this case, the setting value updating process (FIG. 157) may be started from the setting value which is being changed before the supply of the operating power is stopped, and the current use target stored in the setting reference area 341 is used. The configuration may be started from the set value of.

Further, in the case where the supply of the operating power is stopped in the situation where the set value updating process (FIG. 157) is being executed and the “RAM clear operation” is performed when the supply of the operating power is resumed, The setting value updating process (FIG. 157) may be executed without executing the RAM clearing process (step SA416), and the RAM clearing process (step SA416) is executed after the setting value updating process (FIG. 157) is executed. May be configured to be executed. In this case, the setting value updating process (FIG. 157) may be started from the setting value which is being changed before the supply of the operating power is stopped, and the current use target stored in the setting reference area 341 is used. The configuration may be started from the set value of.

Further, in the case where the supply of the operating power is stopped in the situation where the setting confirmation process (FIG. 155) is being executed and the “RAM clear operation” is performed when the supply of the operating power is resumed, The setting confirmation process (FIG. 155) may be executed after the RAM clearing process (step SA416) is executed, and the setting confirmation process (FIG. 155) may be executed without executing the RAM clearing process (step SA416). May be executed, or the RAM clearing process (step SA416) may be executed after the setting confirmation process (FIG. 155) is executed.

Further, in the case where the supply of the operating power is stopped while the setting value updating process (FIG. 157) is being executed, and the “setting change operation” is performed when the supply of the operating power is resumed, Although the setting value update process (FIG. 157) is configured to start from the setting value of the current use target stored in the setting reference area 341, the setting value update process (FIG. 157) stops the supply of operating power. The configuration may be started from the set value that is being changed before the change.

Further, if the “setting change operation” is performed when the supply of the operating power is resumed when the supply of the operating power is stopped while the set value updating process (FIG. 157) is being executed, The setting value update process (FIG. 157) may be executed without executing the RAM clear process (step SA416), and the RAM clear process (step SA416) is executed after the setting value update process (FIG. 157) is executed. May be configured to be executed. In this case, the setting value updating process (FIG. 157) may be started from the setting value which is being changed before the supply of the operating power is stopped, and the current use target stored in the setting reference area 341 is used. The configuration may be started from the set value of.

Further, if the setting change operation is performed when the supply of the operating power is resumed when the supply of the operating power is stopped while the setting confirmation process (FIG. 155) is being executed, Although the setting value update processing (FIG. 157) is configured to start from the setting value of the current use target stored in the setting reference area 341, the setting value update processing (FIG. 157) stops the supply of operating power. The configuration may be started from the set value that is being changed before the change.

Further, if the setting change operation is performed when the supply of the operating power is resumed when the supply of the operating power is stopped while the setting confirmation process (FIG. 155) is being executed, The setting value updating process (FIG. 157) may be executed without executing the RAM clearing process (step SA416), and the RAM clearing process (step SA416) is executed after the setting value updating process (FIG. 157) is executed. May be configured to be executed.

Further, in the case where the supply of operating power is stopped in the situation where the setting confirmation process (FIG. 155) is being executed and the “setting change operation” is performed when the supply of operating power is resumed, The setting confirmation process (FIG. 155) may be executed and the setting value update process (FIG. 157) may not be executed, and the setting value update process (FIG. 157) may be executed after the setting confirmation process (FIG. 155) is executed. The configuration may be executed, or the setting confirmation process (FIG. 155) may be executed after the setting value update process (FIG. 157) is executed. Further, in the case where the supply of operating power is stopped in the situation where the setting confirmation process (FIG. 155) is being executed and the “setting change operation” is performed when the supply of operating power is resumed, Both the setting confirmation process (FIG. 155) and the setting value update process (FIG. 157) may not be executed.

Further, in the case where the supply of the operating power is stopped in the situation where the setting value updating process (FIG. 157) is being executed and the “setting confirmation operation” is performed when the supply of the operating power is resumed, The setting value update process (FIG. 157) is not limited to the configuration started from the setting value that is being changed before the supply of the operating power is stopped, and the setting value update process (FIG. 157) is not limited to the setting reference area. The configuration may be started from the setting value of the current usage target stored in 341.

Further, in the case where the supply of operating power is stopped while the setting value updating process (FIG. 157) is being executed, and the “setting confirmation operation” is performed when the supply of operating power is resumed The configuration clearing process (FIG. 157) may be executed after the RAM clearing process (step SA416) is executed, and the RAM clearing process (step SA416) may be executed after the setting value updating process (FIG. 157) is executed. It may be configured to be executed.

In addition, when the supply of operating power is stopped while the setting value update process (FIG. 157) is being performed, the setting is confirmed when the “setting confirmation operation” is performed when the supply of operating power is resumed. The configuration confirmation process (FIG. 155) may be executed without executing the value update process (FIG. 157). In this case, the setting value information stored in the setting reference area 341 may be overwritten in the setting update area 342 at the start of the next setting value update process (FIG. 157).

Further, in the case where the supply of the operating power is stopped in the situation where the setting value updating process (FIG. 157) is being executed and the “setting confirmation operation” is performed when the supply of the operating power is resumed, The setting confirmation process (FIG. 155) may be executed after the setting confirmation process (FIG. 155) is executed, and the setting confirmation process (FIG. 155) may be executed after the setting value update process (FIG. 157) is executed. ) May be configured to be executed. Further, in the case where the supply of the operating power is stopped in the situation where the setting value updating process (FIG. 157) is being executed and the “setting confirmation operation” is performed when the supply of the operating power is resumed, Both the setting confirmation process (FIG. 155) and the setting value update process (FIG. 157) may not be executed.

Further, when the supply of the operating power is started in the situation where the setting update display flag in the work area 221 for specific control is set to "1", the power-on initial setting process (step SA401) is used for weighting. After the predetermined time has elapsed, the interrupt of the second timer interrupt process (FIG. 134) is permitted, and the setting value is stored in the display and setting update area 342 indicating that the setting value is being updated. The display showing the set value corresponding to the information is not limited to the configuration started by the first to fourth notification display devices 201 to 204, and the display of these weights without waiting for the elapse of the predetermined time. The display may be started. In addition, even if the setting update display flag is set to "1", the setting value is updated on condition that the setting value update process (Fig. 157) is being executed. The display and the setting value corresponding to the information stored in the setting update area 342 may be displayed on the first to fourth notification display devices 201 to 204. In this case, it is possible to prevent these displays from being displayed in a situation where the setting value update processing (FIG. 157) is not executed.

Further, when the supply of the operating power is started in the situation where the setting confirmation display flag in the work area 221 for specific control is set to "1", the power-on initial setting process (step SA401) is used for weight After the predetermined time has elapsed, the interrupt of the second timer interrupt process (FIG. 134) is permitted, and the display and setting reference area 341 indicate that the setting value is being confirmed. The display showing the set value corresponding to the information is not limited to the configuration started by the first to fourth notification display devices 201 to 204, and the display of these weights without waiting for the elapse of the predetermined time is performed. The display may be started. Further, even if "1" is set in the setting confirmation display flag, the setting value is being confirmed on condition that the setting confirmation process (FIG. 155) is being executed. The display and the setting value corresponding to the information stored in the setting update area 342 may be displayed on the first to fourth notification display devices 201 to 204. In this case, it is possible to prevent these displays from being displayed when the setting confirmation process (FIG. 155) is not being executed.

Further, in the situation where the setting value update processing (FIG. 157) is being executed, it is possible to have a configuration in which an image indicating that the setting value is being updated is displayed on the symbol display device 41, and the display is performed. In addition to or instead of the above, an image showing an operation procedure for updating the set value may be displayed, and the display light emitting unit 53 or the speaker unit 54 may update the set value. The configuration may be such that the notification is given. In this case, it becomes possible for the manager of the game hall to clearly recognize that the setting value update process (FIG. 157) is being executed.

Further, in the situation where the setting confirmation process (FIG. 155) is being executed, an image indicating that the setting value is being confirmed is displayed on the symbol display device 41, and the display may be performed. In addition to or instead of the above, an image showing an operation procedure for confirming the set value may be displayed, and the display light emitting unit 53 or the speaker unit 54 may confirm the set value. The configuration may be such that the notification is given. In this case, it becomes possible for the manager of the game hall to clearly recognize that the setting confirmation process (FIG. 155) is being executed.

Further, the operation section operated to update the set value in the set value update process (FIG. 157) is not limited to the reset button 68c, and may be a dedicated operation section such as the update button 68b. It may be an operation unit provided in main controller 60 for canceling the abnormal state. Further, the position corresponding to each of "Setting 1" to "Setting 6" is set as the rotation operation position when the setting key is inserted into the setting key insertion portion 68a and the rotation operation is performed. A set value corresponding to the rotational operation position of the portion 68a may be set. Further, the setting key insertion portion 68a is configured to be able to be rotated further than the ON position, and each time the rotating operation beyond the ON position is performed, the set value being updated becomes the set value in the next order. The configuration may be updated.

Further, when the set value updating process (FIG. 157) is executed, the pachinko machine 10 may be configured to externally output a signal corresponding to the game hall management computer. In this case, the signal output may be performed for a predetermined period (for example, 100 milliseconds) set in advance, and the signal output is continued while the set value update processing (FIG. 157) is executed. It can be configured as well. As a result, it becomes possible for the management computer in the game hall to recognize that the setting value update processing (FIG. 157) has been executed in the pachinko machine 10.

Further, when the setting confirmation process (FIG. 155) is executed, the pachinko machine 10 may be configured to externally output a signal corresponding to the game hall management computer. In this case, the signal output may be performed for a predetermined period (for example, 100 milliseconds) set in advance, and the signal output is continued while the setting confirmation process (FIG. 155) is executed. It can be configured as well. As a result, it becomes possible for the management computer in the game hall to recognize that the setting confirmation process (FIG. 155) has been executed in the pachinko machine 10.

In addition, the configuration in which the processing is terminated when the key insertion unit is changed from the ON state to the OFF state is applied to processing other than the setting confirmation processing (FIG. 155) and the setting value update processing (FIG. 157). Good. For example, in order to display the base value on the first to fourth notification display devices 201 to 204, the predetermined key insertion part needs to be operated to the ON position, and the predetermined key insertion part is turned on. The display may be terminated when it is specified that the state has been changed to the OFF state.

Further, as a condition for starting the set value updating process (FIG. 157), a condition may be set such that at least one of the gaming machine body 12 and the front door frame 14 is operated to be opened. .. In the configuration, when the supply of the operating power is stopped in the situation where the set value updating process (FIG. 157) is being executed and “no operation” is performed when the supply of the operating power is restarted, or the “setting confirmation operation” is performed. The configuration may be such that the setting value update process (FIG. 157) is started even if the opening target has not been operated to open.

Further, as a condition for starting the setting confirmation process (FIG. 155), a condition may be set such that at least one of the gaming machine body 12 and the front door frame 14 is operated to be opened. .. In the configuration, in the case where the supply of the operating power is stopped in the situation where the setting confirmation process (FIG. 155) is being executed and “there is no operation” when restarting the supply of the operating power, the above-mentioned opening is performed. The configuration confirmation process (FIG. 155) may be started even if the target has not been opened.

Further, the main RAM 65 is initialized by a RAM clear process executed before the set value update process (FIG. 157) is executed and a RAM clear process executed without executing the set value update process. The target areas may be different.

Further, when the setting value update process (FIG. 157) is started in the situation where “1” is not set in the setting update display flag, the setting value corresponding to the information stored in the setting reference area 341 is changed. The configuration is not limited to the configuration in which the setting value is changed, and the configuration may be configured such that the setting value is changed from the preset setting value of the initial value. The initial value may be, for example, "setting 1", "setting 6", or any other setting value.

Further, in addition to or instead of the configuration in which the setting value update process (FIG. 157) is executed as the process at the start of the supply of the operating power, in the situation after the process at the start of the supply of the operating power is completed, the “setting change operation The setting value update process (FIG. 157) may be executed based on the fact that "." Even with this configuration, if the setting value update processing (FIG. 157) ends before the normal termination trigger occurs, the setting value update processing (FIG. 157) is executed even if the “setting change operation” is not performed. With the configuration that is executed, it is possible to give priority to the work of changing the set value.

Further, in addition to or instead of the configuration in which the setting confirmation process (FIG. 155) is executed as a process at the time of starting the supply of the operating power, the “setting confirmation operation The configuration confirmation process (FIG. 155) may be executed based on the fact that "." Even with this configuration, if the setting confirmation process (FIG. 155) is completed before the normal termination trigger occurs, the setting confirmation process (FIG. 155) is executed even if the “setting confirmation operation” is not performed. With the configuration that is executed, it is possible to give priority to the work of confirming the set value.

<46th Embodiment>
In this embodiment, the processing configuration of the main processing executed by the main CPU 63 is different from that in the 45th embodiment. The configuration different from that of the 45th embodiment will be described below. The description of the same configuration as that of the forty-fifth embodiment is basically omitted.

FIG. 161 is a flowchart showing the main processing executed in the main CPU 63 in this embodiment. The processes of steps SA901 to SA925 in the main process are executed by using the specific control program and the specific control data in the main CPU 63.

In steps SA901 to SA904, the same processing as steps SA401 to SA404 of the main processing (FIG. 153) in the forty-fifth embodiment is executed. Then, it is determined whether or not the setting update display flag provided in the specific control work area 221 is set to "1" (step SA905). When the supply of the operating power is resumed after the supply of the operating power is stopped in the situation where the setting value updating process (step SA918) is being executed, the setting update display flag is set to "1". In, the main processing is started.

When a negative determination is made in step SA905, it is determined whether or not the reset button 68c has been pressed (step SA906). That is, it is determined whether or not the power of the pachinko machine 10 is turned on while the reset button 68c is being pressed and the supply of operating power to the main CPU 63 is started.

When the reset button 68c has not been pressed (step SA906: NO), it is determined whether or not "1" is set in the power failure flag provided in the work area 221 for specific control (step SA907). When the power failure information storage processing (step S8901) of the first timer interrupt processing (FIG. 133) executes the power failure processing, the power failure flag is set to "1". The power outage flag is a flag for the main CPU 63 to specify whether or not the power outage process was appropriately performed at the previous power off time.

When "1" is set in the power failure flag (step SA907: YES), checksums are calculated for the specific control work area 221 and the specific control stack area 222 (step SA908). The method of calculating the checksum is the same as in the 33rd embodiment. After that, the specific control work area 221 and the specific control work area 221 which are calculated and stored in the specific control work area 221 in the power failure process executed immediately before the supply of the operating power to the main CPU 63 is stopped. The checksum for the stack area 222 is read, and the read checksum is compared with the checksum calculated in step SA908 (step SA909). Then, it is determined whether the checksums match (step SA910).

If a negative determination is made in step SA907 or step SA910, that is, if the power failure flag is not set to "1" or the checksums do not match, the game stop flag provided in the work area 221 for specific control Is set to "1" (step SA911). Further, at the start of supplying the operating power, an abnormality command indicating that an abnormality has occurred with respect to the power failure flag or the checksum is transmitted to the sound emission control device 81 (step SA912). The processing contents of these steps SA911 and SA912 are the same as those of steps SA410 and SA411 of the main processing (FIG. 153) in the forty-fifth embodiment.

When the power failure flag is set to "1" and the checksum is normal (step SA907 and step SA910: YES), it is determined whether the setting key insertion unit 68a is turned on by using the setting key. (Step SA913). When the setting key insertion unit 68a is turned on using the setting key (step SA913: YES), the setting confirmation process is executed (step SA914). The processing content of the setting confirmation processing is the same as that in the 45th embodiment. That is, in the present embodiment, even if the setting confirmation display flag provided in the work area 221 for specific control is set to "1", the setting confirmation process is executed unless the setting key insertion portion 68a is turned on. Not done. Therefore, even if the supply of the operating power is stopped while the setting confirming process is being executed, the setting confirming process is not executed unless the supply of the operating power is restarted in the condition where the “setting confirming operation” is performed.

When "1" is set in the setting update display flag (step SA905: YES) or when the reset button 68c is pressed (step SA906: YES), the RAM clearing process is executed (step SA915). The contents of the RAM clearing process are the same as the RAM clearing process (step SA416) of the main process (FIG. 153) in the 45th embodiment.

After that, when the setting update display flag is set to "1" (step SA916: YES), the setting value update process is executed regardless of whether the setting key insertion portion 68a is turned ON (step SA916). SA918). On the other hand, when "1" is not set in the setting update display flag (step SA916: NO), the setting value is updated on condition that the setting key insertion part 68a is turned on (step SA917: YES). The process is executed (step SA918). That is, when the supply of the operating power is stopped while the set value updating process is being executed, the RAM clearing process (step The setting value update process (step SA918) is newly started after SA915 is executed.

When the process of step SA912 is executed, the negative determination is made in step SA913, the process of step SA914 is executed, the negative determination is made in step SA917, or the process of step SA918 is executed, the step SA919 is executed. ~ The process of step SA925 is executed. The processing contents of steps SA919 to SA925 are the same as those of steps SA419 to SA425 of the main processing (FIG. 153) in the 45th embodiment.

FIG. 162 shows a main process when resuming the supply of operating power after the power failure process is executed in the situation where the setting value update process (step SA918) or the setting confirmation process (step SA914) is executed. It is explanatory drawing for demonstrating the content of the process performed in FIG. 161).

When neither the set value update process (step SA918) nor the setting confirmation process (step SA914) is executed and the power failure process is executed, the main process (Fig. The contents of the process executed in () are the same as those in the 45th embodiment. That is, when the supply of operating power is restarted in the "no operation" situation, the RAM clearing process (step SA915), the set value updating process (step SA918), and the setting confirming process (step) in the main process (FIG. 161). Neither SA 914) is executed. Further, when the supply of operating power is restarted in the state where the “RAM clear operation” is performed, the RAM clear process (step SA915) is executed in the main process (FIG. 161), while the set value update process (step SA915) is executed. SA918) and the setting confirmation process (step SA914) are not executed. When the supply of operating power is restarted in the situation where the “setting change operation” is performed, the RAM clearing process (step SA915) is executed in the main process (FIG. 161) and the setting value updating process (step SA918) is executed. While being executed, the setting confirmation process (step SA914) is not executed. When the supply of operating power is restarted while the "setting confirmation operation" is performed, the setting confirmation processing (step SA914) is executed in the main processing (FIG. 161), while the RAM clear processing (step SA915). Also, the setting value updating process (step SA918) is not executed.

Next, when the power failure process is executed in the situation where the set value update processing (step SA918) is being executed (that is, the situation where the setting update display flag is set to "1"), the subsequent supply of operating power The contents of the process executed in the main process (FIG. 161) when the process is restarted will be described.

If the operating power supply is restarted in the "no operation" situation, if the operating power supply is restarted in the "RAM clear operation" situation, the operation is performed in the "setting change operation" situation The RAM clearing process (step SA915) is performed in the main process (FIG. 161) regardless of whether the power supply is restarted or the operating power supply is restarted in the situation where the “setting confirmation operation” is performed. ) Is executed and the setting value updating process (step SA918) is executed, while the setting confirmation process (step SA914) is not executed. That is, when the power failure process is executed in the situation where the set value update process (step SA918) is being executed, the RAM clearing is performed regardless of the operation content when restarting the supply of the operating power thereafter. After the process (step SA915) is executed, the set value update process (step SA918) is newly started.

With the above configuration, when the supply of the operating power is stopped in the middle of the set value updating process (step SA918), when the supply of the operating power is restarted, the setting key insertion portion when the power of the pachinko machine 10 is turned on. Regardless of the operation contents of the 68a and the reset button 68c, it is possible to newly start the set value updating process (step SA918) after the RAM clearing process (step SA915) is executed. With this, when the supply of the operating power is stopped in the middle of updating the set value, when the supply of the operating power is resumed after that, the opportunity to complete the setting value after the update is surely generated. It becomes possible. Therefore, when the supply of the operating power is resumed after the supply of the operating power is stopped while the set value is being updated, the setting before the previous setting value update process (step SA918) is started It is possible to prevent the game from being started with the value kept.

Further, when the supply of the operating power is stopped in the middle of the set value updating process (step SA918), the RAM clearing process (step SA915) is uniquely executed irrespective of the operation content when restarting the supply of the operating power. By executing the set value updating process (step SA918) after the above, the process configuration is simplified as compared to the configuration in which the process content executed according to each operation content is changed. It is possible to achieve the effect.

Next, when the power failure processing is executed in the situation where the setting confirmation processing (step SA914) is being executed (that is, the setting confirmation display flag is set to "1"), the subsequent supply of operating power The contents of the process executed in the main process (FIG. 161) when the process is restarted will be described.

When the power failure process is executed in the situation where the setting confirmation processing (step SA914) is being executed (that is, the setting confirmation display flag is set to “1”) The content of the processing executed in the processing (FIG. 161) is that the processing at the time of power failure is executed in a situation where neither the setting value update processing (FIG. 157) nor the setting confirmation processing (FIG. 155) is executed. At the time of resuming the supply of operating power thereafter, the contents are the same as the contents of the process executed in the main process (FIG. 161). That is, even if the supply of the operating power is stopped in the situation where the setting confirmation process (step SA914) is being executed, if the supply of the operating power is resumed after that, the power of the pachinko machine 10 is turned on. The process corresponding to the operation content is executed.

Different from the change of the set value, the confirmation of the set value does not affect the game even if it is ended midway and not restarted. Therefore, even if the supply of the operating power is stopped during the execution of the confirmation of the set value, the process corresponding to the operation content at the time of turning on the power of the pachinko machine 10 is executed so that the game hall manager It is possible to give priority to the operation content when the power is turned on.

<Forty-seventh Embodiment>
In the present embodiment, when the setting value update process (step SA918) or the setting confirmation process (step SA914) is executed and the power failure process is executed, the main process ( The contents of the processing executed in FIG. 161) are different from those in the 45th embodiment. The configuration different from that of the 45th embodiment will be described below. The description of the same configuration as that of the forty-fifth embodiment is basically omitted.

FIG. 163 shows the main process when restarting the supply of operating power after the power failure process is executed in the situation where the setting value update process (FIG. 157) or the setting confirmation process (FIG. 155) is being executed. FIG. 153 is an explanatory diagram for explaining the content of the processing executed in FIG. 153).

When neither the setting value update process (FIG. 157) nor the setting confirmation process (FIG. 155) is executed in the situation where the power failure process is executed, the main process (FIG. The contents of the process executed in () are the same as those in the 45th embodiment. Further, when the power failure process is executed in the situation where the setting confirmation process (step FIG. 155) is being executed (that is, the condition in which the setting confirmation display flag is set to “1”), the subsequent supply of operating power is performed. The contents of the process executed in the main process (FIG. 153) when the process is restarted are the same as those in the 46th embodiment.

When the power outage process is executed in the situation where the setting value update process (FIG. 157) is being executed (that is, the condition where the setting update display flag is set to “1”), the main operation is performed when the supply of operating power is resumed. As for the contents of the processing executed in the processing (FIG. 153), in the case of “no operation” and “setting confirmation operation”, the setting value update processing (FIG. 157) is restarted as in the 45th embodiment. Is. In the case of the “RAM clear operation” and the “setting change operation”, the set value update processing (FIG. 157) is restarted after the RAM clear processing (step SA416) is executed. In this case, in the RAM clear processing (step SA416), not only the setting reference area 341 provided in the specific control work area 221, but also the setting update display flag and the setting update display flag provided in the specific control work area 221 are set. The area 342 is excluded from the initialization target. Therefore, even if the RAM clearing process (step SA416) is executed in a situation where the setting update display flag is set to "1", the setting update display flag is set to the setting update display flag at the start of the subsequent setting value update process (FIG. 157). The state is set to "1", and the update of the set value is started from the information of the set value stored in the setting update area 342 at that time.

With the above configuration, when the supply of the operating power is stopped during the updating of the set value, the set value updating process (FIG. 157) is not only reliably executed when the supply of the operating power is resumed thereafter. It is possible to restart the update of the set value from the set value that is being updated immediately before the supply of the operating power is stopped. This makes it possible to continue the work of changing the set value.

<48th Embodiment>
In the present embodiment, when the setting value update process (step SA918) or the setting confirmation process (step SA914) is executed and the power failure process is executed, the main process ( The contents of the processing executed in FIG. 161) are different from those in the 45th embodiment. The configuration different from that of the 45th embodiment will be described below. The description of the same configuration as that of the forty-fifth embodiment is basically omitted.

FIG. 164 shows the main process (restart of the supply of operating power) after the power failure process is executed when the setting value update process (FIG. 157) or the setting confirmation process (FIG. 155) is executed. FIG. 153 is an explanatory diagram for explaining the content of the processing executed in FIG. 153).

When neither the setting value update process (FIG. 157) nor the setting confirmation process (FIG. 155) is executed in the situation where the power failure process is executed, the main process (FIG. The contents of the process executed in () are the same as those in the 45th embodiment. Further, when the power failure process is executed in the situation where the setting confirmation process (step FIG. 155) is being executed (that is, the condition in which the setting confirmation display flag is set to “1”), the subsequent supply of operating power is performed. The contents of the process executed in the main process (FIG. 153) when the process is restarted are the same as those in the 46th embodiment.

When the power outage process is executed in the situation where the setting value update process (FIG. 157) is being executed (that is, the condition where the setting update display flag is set to “1”), the main operation is performed when the supply of operating power is resumed. The contents of the processing executed in the processing (FIG. 153) are “no operation”, “RAM clear operation” and “setting confirmation operation”, the set value update processing (FIG. 157) and the setting confirmation. When the power outage process is executed in a situation where none of the power consumption process (FIG. 155) is executed, the same content as the process executed in the main process (FIG. 153) when the supply of operating power is resumed after that Is. That is, in the case of "no operation", the RAM clear process (step SA416), the set value update process (Fig. 157), and the setting confirmation process (Fig. 155) are not all executed, and the "RAM clear operation" is performed. In this case, the RAM clearing process (step SA416) is executed, but the setting value updating process (FIG. 157) and the setting confirmation process (FIG. 155) are not executed. Although the setting confirmation process (FIG. 155) is executed, the RAM clear process (step SA416) and the set value update process (FIG. 157) are not executed.

On the other hand, in the case of the "setting change operation", the RAM clearing process (step SA416) is executed and then the setting value updating process (Fig. 157) is restarted. In this case, in the RAM clear processing (step SA416), not only the setting reference area 341 provided in the specific control work area 221, but also the setting update display flag and the setting update display flag provided in the specific control work area 221 are set. The area 342 is excluded from the initialization target. Therefore, even if the RAM clearing process (step SA416) is executed in a situation where the setting update display flag is set to "1", the setting update display flag is set to the setting update display flag at the start of the subsequent setting value update process (FIG. 157). The state is set to "1", and the update of the set value is started from the information of the set value stored in the setting update area 342 at that time.

With the above configuration, even if the supply of the operating power is stopped while the set value is being updated, it corresponds to the operation content by the manager of the game hall when the supply of the operating power is resumed thereafter. It is possible to give priority to the execution of processing.

Also, if the supply of operating power is stopped while the set value is being updated, and if the supply of operating power is restarted in the situation where the “setting change operation” was performed, the supply of operating power It is possible to restart the update of the set value from the set value that is being updated immediately before the stop. This makes it possible to continue the work of changing the set value.

<49th Embodiment>
In this embodiment, the processing configuration of the main processing executed by the main CPU 63 is different from that in the 45th embodiment. The configuration different from that of the 45th embodiment will be described below. The description of the same configuration as that of the forty-fifth embodiment is basically omitted.

FIG. 165 is a flowchart showing the main processing executed in the main CPU 63 in this embodiment. The processes of steps SB101 to SB128 in the main process are executed by using the program for specific control and the data for specific control in the main CPU 63.

First, power-on initialization processing is executed (step SB101). In the power-on initialization process, for example, a predetermined wait time (specifically, 1 second) elapses after the main process is started, and the process waits without proceeding to the next process. In the predetermined period for this weight, the operation start and initial setting of the symbol display device 41 are completed. Also, access to the main RAM 65 is permitted.

After that, the internal function register setting process is executed (step SB102). In the internal function register setting process, as in the 35th embodiment, the interrupt period of the first timer interrupt process (FIG. 133), which is a process that is activated by periodically interrupting the main process, is set to the first interrupt period. (Specifically, 4 ms), and the interrupt period of the second timer interrupt process (FIG. 134), which is a process that is periodically interrupted and activated with respect to the main process, is set from the first interrupt period. Is set to the second interrupt cycle (specifically, 2 milliseconds) which is a short cycle.

That is, in this embodiment, as in the 35th embodiment, the first timer interrupt processing (FIG. 133) and the second timer interrupt processing (FIG. 134) are performed so that the interrupt cycle becomes relatively short as the timer interrupt processing. And exist. Both the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134) are activated by interrupting the main process. The second timer interrupt process (FIG. 134) is activated by interrupting the first timer interrupt process (FIG. 133). On the other hand, the first timer interrupt process (FIG. 133) does not start by interrupting the second timer interrupt process (FIG. 134). In addition, when both the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134) are not executed, and when both the first interrupt cycle and the second interrupt cycle have passed, those cycles The second timer interrupt processing (FIG. 134) is started first regardless of the lapsed order of the above. In this respect, it can be said that the second timer interrupt process (FIG. 134) is a process that is activated prior to the first timer interrupt process (FIG. 133). However, the configuration is not limited to this, and the first timer interrupt process (FIG. 133) may be activated prior to the second timer interrupt process (FIG. 134).

In the internal function register setting process, the first interrupt period of the first timer interrupt process (FIG. 133) is set in a predetermined register of the main CPU 63, and the second interrupt period of the second timer interrupt process (FIG. 134) is set. It is set in a specific register of the side CPU 63. Further, in the internal function register setting process, in addition to the setting of the first and second interrupt cycles, the setting process of the numerical range of various counters such as the numerical range of the hit random number counter C1 is executed.

Then, "1" is set to the in-start-up processing flag provided in the work area 221 for specific control (step SB103). As in the 35th embodiment, the start-up processing flag is among the various processes set in the first timer interrupt process (FIG. 133) even if the first timer interrupt process (FIG. 133) is activated. While the power outage monitoring, the processing for updating various counters and the illegality monitoring are executed, the first timer interrupt processing (FIG. 133) should be terminated without executing the processing for advancing the game. This is a flag for specifying by the main CPU 63.

The start-up processing flag is set to "1" when the processing (step SB101 to step SB122) at the start of supplying the operating power is started in the main processing (FIG. 165), and the processing at the start of supplying the operating power is started. It is cleared to "0" before the end of (step SB101 to step SB122) and the start of the residual processing (step SB125 to step SB128). As in the 35th embodiment, in the first timer interrupt process (FIG. 133), when the start-up processing flag is set to "1", the processes of steps S8907 to S8920 are not executed. Thus, in order to advance the game in a situation where a setting confirmation process (FIG. 166) or a set value update process (FIG. 167) described later among the processes at the start of supply of operating power (steps SB101 to SB122) are executed. It is possible to prevent the processing of (1) from being executed. On the other hand, as described above, in the first timer interrupt processing (FIG. 133), even if the start-up processing flag is set to "1", by executing the processing of steps S8901 to S8905, the operating power is reduced. The power failure monitoring is executed even in the situation where the setting confirmation processing (FIG. 166) or the set value update processing (FIG. 167) described later among the processing (steps SB101 to SB122) at the start of supply of is executed. At the same time, the hit random number counter C1, the big hit type counter C2, the reach random number counter C3, and the random number initial value counter CINI are updated, and further fraud detection is executed.

Particularly, even when the start-up processing flag is set to "1", the power failure information storage processing (step S8901) is executed, so that the operation power supply start processing (steps SB101 to SB122) is started. Even if a power outage occurs in the situation where the setting confirmation process (FIG. 166) or the set value update process (FIG. 167) described later is executed, it is possible to execute the power outage process for it. In the power failure process, as in the thirty-fifth embodiment, the power failure flag provided in the specific control work area 221 is set to "1", the checksum is calculated, and the calculated checksum is used for the specific control. Since the data is stored in the work area 221 of No. 1, it is possible to prevent the occurrence of an abnormality in the main RAM 65 when the supply of operating power is restarted. As a result, when a power failure occurs during the setting confirmation process (FIG. 166) or the setting value update process (FIG. 167), the fact that a power failure has occurred during these setting-related processes is supplied to the next operating power. It is possible to specify at the start.

Incidentally, in the situation where the setting confirmation process (FIG. 166) or the set value update process (FIG. 167) is being executed, both the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134) are performed. Interrupts are not prohibited and can be interrupted at any timing. In this case, when the first timer interrupt process (FIG. 133) or the second timer interrupt process (FIG. 134) is activated in the setting confirmation process (FIG. 166) or the set value update process (FIG. 167), The information of the return address of the main process (FIG. 165) for returning after the timer interrupt process that is the activation target is finished is saved in the stack area 222 for specific control, and the timer interrupt process is activated. Information of various registers of the main CPU 63 immediately before is saved in the stack area 222 for specific control. Then, when the timer interrupt process which is the activation target ends, the process returns to the process of the main process (FIG. 165) corresponding to the information of the return address saved in the stack area 222 for specific control, and The information saved in the stack area 222 for specific control is restored to various registers of the main CPU 63.

After setting the start-up processing flag to "1" in step SB103, it is determined whether or not the power failure flag provided in the specific control work area 221 is set to "1" (step SB104). .. When the power failure information storage processing (step S8901) of the first timer interrupt processing (FIG. 133) executes the power failure processing, the power failure flag is set to "1". The power outage flag is a flag for the main CPU 63 to specify whether or not the power outage process was appropriately performed at the previous power off time.

When "1" is set in the power failure flag (step SB104: YES), it is determined whether the checksum is normal (step SB105). Specifically, first, checksums are calculated for the specific control work area 221 and the specific control stack area 222. The method of calculating the checksum is the same as in the 33rd embodiment. After that, the work area 221 for the specific control and the work area 221 for the specific control, which are calculated in the power failure process executed immediately before the supply of the operating power to the main CPU 63 is stopped and stored in the work area 221 for the specific control, are performed. The checksum for the stack area 222 is read, and the read checksum is compared with the checksum calculated as described above in the main processing this time. Then, it is determined whether the checksums match.

If the checksums match (step SB105: YES), is the setting value corresponding to the information stored in the setting reference area 341 (see FIG. 154) in the specific control work area 221 within the normal range? It is determined whether or not (step SB106). The setting reference area 341 is a storage area in which information for specifying the current setting value of the pachinko machine 10 by the main CPU 63 is stored as in the 45th embodiment. When the numerical information of “1” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 1”. When the numerical information of “2” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 2”. When the numerical information of “3” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 3”. When the numerical information of “4” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 4”. When the numerical information of “5” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 5”. When the numerical information of “6” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 6”. In step SB106, it is determined whether or not the setting value information stored in the setting reference area 341 is any one of "1" to "6".

When a positive determination is made in all of steps SB104 to SB106, it is determined whether "1" is set in the setting update display flag provided in the specific control work area 221 (step SB107). The setting update display flag is a flag for the main CPU 63 to specify that the setting value update processing (FIG. 167) is being executed as in the 35th embodiment, and the setting update display flag is set to "1". When is set, a display indicating that the setting value is being updated and a setting value being updated are displayed on the first to fourth notification display devices 201 to 204. The setting update display flag is a flag that is set to "1" when the setting value updating process (Fig. 167) is started and is cleared to "0" when the setting value updating process (Fig. 167) is ended. In the situation where the setting value update process (FIG. 167) is not executed, basically, the setting update display flag is not set to “1”. However, when the supply of operating power to the main CPU 63 is stopped in the situation where the set value updating process (FIG. 167) is being executed, and then the supply of operating power to the main CPU 63 is started. In, the setting update display flag is set to "1". The state in which the setting update display flag is set to "1" is maintained until the process of clearing the setting update display flag to "0" is executed in the setting value update process (FIG. 167).

When a negative determination is made in step SB107 because the setting update display flag is not set to "1", it is determined whether the reset button 68c is pressed (step SB108). That is, it is determined whether or not the power of the pachinko machine 10 is turned on while the reset button 68c is being pressed and the supply of operating power to the main CPU 63 is started. Here, in the present embodiment, as in the 35th embodiment, the main control device 60 is provided with the setting key insertion portion 68a and the reset button 68c, but is not provided with the update button 68b. Further, the main control device 60 is provided with not the first to third notification display devices 69a to 69c but the first to fourth notification display devices 201 to 204 as in the eleventh embodiment.

When the reset button 68c is not pressed (step SB108: NO), it is determined whether or not "1" is set in the game stop flag in the work area 221 for specific control (step SB109). The game stop flag is a flag that is set to "1" when "1" is not set in the power failure flag, when the checksums do not match, or when the set value is abnormal. When the game stop flag is set to "1", the processes of steps S8901 to S8905 are executed in the first timer interrupt process (FIG. 133), while the positive determination is made in step S8906 to steps S8907 to step. The process of S8920 is not executed. As a result, when the power failure flag is not set to “1” because the power failure process was not properly performed at the previous power shutdown, the work area 221 for the specific control and the stack area 222 for the specific control are If at least one of the checksums does not match due to the change in the information storage state since the last power-off, or if the set value is abnormal, power failure monitoring, updating of various counters and illegal operation While the processing for monitoring is executed, the processing for advancing the game is not executed. When an affirmative determination is made in step SB109, the processes of step SB121 and step SB122 described below are executed.

When a negative determination is made in step SB109, it is determined whether or not the setting key insertion unit 68a is turned on by using the setting key (step SB110). When the setting key insertion unit 68a is turned on by using the setting key (step SB110: YES), the setting confirmation process is executed (step SB112). Even when the setting key insertion unit 68a is not turned on by using the setting key (step SB110: NO), the setting confirmation display flag provided in the work area 221 for specific control is set to "1". If is set (step SB111: YES), the setting confirmation process is executed (step SB112).

The setting confirmation display flag is a flag for the main CPU 63 to specify that the setting confirmation process (FIG. 166) is being executed as in the 35th embodiment, and the setting confirmation display flag is "1". If is set, a display indicating that the setting value is being confirmed and a display indicating the currently set setting value are displayed on the first to fourth notification display devices 201 to 204. Be seen. The setting confirmation display flag is a flag that is set to "1" when the setting confirmation process (Fig. 166) is started and is cleared to "0" when the setting confirmation process (Fig. 166) is ended. In the situation where the setting confirmation process (FIG. 166) is not executed, basically, the setting confirmation display flag is not set to "1". However, when the supply of operating power to the main CPU 63 is stopped in the situation where the setting confirmation process (FIG. 166) is being executed, and then the supply of operating power to the main CPU 63 is started. In, the setting confirmation display flag is set to "1". When the setting confirmation display flag is set to "1", the first RAM clearing process (step SB117) described below is executed, the setting value updating process (FIG. 167) described below is executed, or the setting confirmation is executed. It is maintained until the processing for clearing the setting confirmation display flag to "0" is executed in the processing for processing (FIG. 166).

Not only when the reset button 68c is not pressed as described above and the setting key insertion portion 68a is turned on (that is, when the "setting confirmation operation" is performed), the reset button 68c is The setting confirmation process (FIG. 166) is executed by executing the setting confirmation process (FIG. 166) even when the setting confirmation display flag is set to “1” even when the pressing operation is not performed. When the power failure process is executed under the above condition, the setting confirmation process (FIG. 166) is executed even if the “setting confirmation operation” is not performed when the supply of the operating power is subsequently restarted. As a result, it becomes possible to continuously confirm the current set value of the pachinko machine 10. On the other hand, even when the power failure process is executed in the situation where the setting confirmation process (FIG. 166) is being executed, if the reset button 68c is pressed when restarting the supply of operating power, Without performing the setting confirmation process (FIG. 166), the first RAM clear process (step SB117) and the set value update process (FIG. 167) are executed corresponding to the operation performed when the supply of the operating power is restarted. To be done. As a result, the execution of the first RAM clearing process (step SB117) or the setting value updating process (FIG. 167) can be prioritized over the setting confirmation process (FIG. 166).

Here, the setting confirmation process executed in step SB112 will be described. FIG. 166 is a flowchart showing the setting confirmation process. The processing of steps SB201 to SB207 in the setting confirmation processing is executed by using the specific control program and specific control data in the main CPU 63.

First, interrupt permission is set (step SB201). As a result, the first timer interrupt process (FIG. 133) is interrupted and activated in the first interrupt cycle, and the second timer interrupt process (FIG. 134) is interrupted and activated in the second interrupt period.

In this embodiment, in the process (step SB101 to step SB122) at the start of supplying the operating power, the interrupts of the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134) are basically prohibited. In the setting confirmation process (FIG. 166) and the setting value update process (FIG. 167), interruption is permitted. Therefore, in the situation where the setting confirmation process (FIG. 166) and the set value update process (FIG. 167) are not executed in the process (step SB101 to step SB122) at the time of starting the supply of the operating power, the first timer interrupt process (FIG. 133) and the execution of the second timer interrupt processing (FIG. 134) are prohibited, and the setting confirmation processing (FIG. 166) or the set value updating processing (FIG. 167) is being executed, the first timer interrupt processing (FIG. 133). ) And the execution of the second timer interrupt process (FIG. 134) are permitted. However, in the situation where the setting confirmation process (FIG. 166) or the set value update process (FIG. 167) is being executed, since the start-up processing flag is set to “1”, the first timer interrupt processing (FIG. Even if 133) is activated, among the various processes of the first timer interrupt process (FIG. 133), the processes for performing power failure monitoring, updating various counters, and fraudulent monitoring are executed, while progressing the game. The first timer interrupt process (FIG. 133) is terminated without executing the process.

After that, "1" is set to the setting confirmation display flag on condition that "1" is not set to the setting confirmation display flag provided in the work area 221 for specific control (step SB202). When the setting confirmation display flag is set to "1", an affirmative determination is made in step S9005 of the second timer interrupt processing (FIG. 134). (Step S9006) is executed. The processing contents of the setting processing for the fifth display data buffer 275 during the setting confirmation are the same as those in the 45th embodiment. As a result of the processing being performed, a display indicating that the setting value of the pachinko machine 10 is being confirmed and the current setting value of the pachinko machine 10, as shown in the explanatory view of FIG. Is displayed on the first to fourth notification display devices 201 to 204.

After that, the confirmation start command is transmitted to the voice emission control device 81 (step SB203). Upon receiving the confirmation start command, the sound emission control device 81 recognizes the image indicating that the setting confirmation process (FIG. 166) is being executed and the operation content for ending the setting confirmation process (FIG. 166). The display control device 82 is controlled so that the image for enabling is displayed on the symbol display device 41. This allows the manager of the game hall to recognize that the current setting value of the pachinko machine 10 is being confirmed, and is necessary for ending the setting confirmation process (FIG. 166). It is possible for the manager of the game hall to recognize various operation contents. In addition to or instead of the above-mentioned notification being performed by the symbol display device 41, at least one of the display light emitting unit 53 and the speaker unit 54 may be configured. Further, it may be configured that an external output indicating that the setting confirmation process (FIG. 166) is being executed is performed to a device outside the pachinko machine 10 such as a game hall management computer.

After that, the setting key inserting unit 68a determines whether or not the ON state is switched to the OFF state by using the setting key (step SB204). Specifically, similarly to the setting confirmation process (FIG. 155) in the forty-fifth embodiment, the reception state of the signal received from the detection sensor that detects the state of the setting key insertion portion 68a corresponds to the ON state. It is determined whether the reception state corresponding to the OFF state has been changed to the reception state corresponding to the OFF state. Therefore, not only when the setting key insertion section 68a is maintained in the ON state, but also when the setting confirmation processing (FIG. 166) is started in the situation where the setting key insertion section 68a is in the OFF state, the OFF state is set. Even if it is maintained, a negative determination is made in step SB204. When it is not specified that the setting key insertion unit 68a has switched from the ON state to the OFF state (step SB204: NO), the process of step SB204 is repeated.

When it is specified that the setting key insertion unit 68a has been switched from the ON state to the OFF state (step SB204: YES), the setting confirmation display flag in the specific control work area 221 is cleared to "0" (step SB205). As a result, a negative determination is made in step S9005 of the second timer interrupt processing (FIG. 134), so that the setting processing (step S9006) for the fifth display data buffer 275 during the setting confirmation is not executed. Therefore, on the first to fourth notification display devices 201 to 204, a display indicating that the current setting value of the pachinko machine 10 is being confirmed and a display indicating the current setting value of the pachinko machine 10 are displayed. The state to be performed is released.

After that, the interruption is prohibited (step SB206). As a result, when the setting confirmation process (FIG. 166) is terminated and the process returns to the process (step SB101 to step SB122) at the start of supply of operating power in the main process (FIG. 165), the first timer interrupt process (FIG. 133) and the interrupt of the second timer interrupt processing (FIG. 134) are prohibited.

After that, a return command for confirmation is transmitted to the voice emission control device 81 (step SB207). By receiving the return command at the time of confirmation, the sound emission control device 81 identifies that the processing (step SB101 to step SB122) at the time of starting the supply of the operating power is completed in the main CPU 63, and at the same time, confirms the operation power of this time. It is specified that the setting confirmation process (FIG. 166) has been executed in the process at the start of supply (step SB101 to step SB122). Then, the processing corresponding to the reception of the confirmation return command is executed. The contents of the processing will be described later.

As described above, when the power of the pachinko machine 10 is turned on while the setting key insertion portion 68a is turned on by the setting key without pressing the reset button 68c, the supply of operating power to the main CPU 63 is started. In the situation where the main process (FIG. 165) has been started and the reset button 68c has not been pressed and the setting key insertion portion 68a has been turned ON, the game is advanced in the main process (FIG. 165). The setting confirmation process (FIG. 166) is executed in a state before the process of (1) is executed, which is a process at the time of starting the supply of the operating power. As a result, it becomes possible to confirm the set value in a situation where the game is not being played.

Returning to the explanation of the main processing (FIG. 165), when the setting key insertion unit 68a has not been turned on using the setting key and "1" has not been set in the setting confirmation display flag (step SB110 and (Step SB111: NO), the normal recovery command is transmitted to the voice emission control device 81 (step SB113). The voice emission control device 81 receives the normal recovery command to identify that the main CPU 63 has completed the process (steps SB101 to SB122) at the time of starting the supply of the operating power, and starts the supply of the operating power this time. It is specified that the first RAM clearing process (step SB117), the setting confirmation process (FIG. 166), and the setting value updating process (FIG. 167) are not executed in the process (steps SB101 to SB122) at that time. .. Then, the processing corresponding to the reception of the normal return command is executed. The contents of the processing will be described later.

On the other hand, when it is determined in step SB108 that the reset button 68c has been pressed, and it is determined that the setting key insertion portion 68a has been turned ON using the setting key (steps SB108 and SB114). : YES), or when it is determined in step SB107 that the setting update display flag is set to "1", the setting value update process is executed (step SB115). Not only when the reset button 68c is pressed and the setting key insertion portion 68a is turned ON (that is, when the "setting change operation" is performed) as described above, the reset button 68c Setting value update processing (FIG. 167) is executed even when the setting update display flag is set to "1" regardless of whether or not the pressing operation and the ON operation of the setting key insertion unit 68a are performed, thereby updating the setting value. When the process at the time of power failure is executed in the situation where the process (FIG. 167) is being executed, the operation content at the time of starting the supply of the operating power thereafter is “no operation”, “RAM clear operation”, “setting change”. Regardless of whether it is an “operation” or a “setting confirmation operation”, the setting value update processing (FIG. 167) is executed. As a result, it becomes possible to give priority to the execution of the setting value update processing (FIG. 167).

Here, the setting value update processing executed in step SB115 will be described. FIG. 167 is a flowchart showing the set value updating process. Note that the processing of steps SB301 to SB314 in the setting value update processing is executed using the program for specific control and the data for specific control in the main CPU 63.

First, interrupt permission is set (step SB301). As a result, the first timer interrupt process (FIG. 133) is interrupted and activated in the first interrupt cycle, and the second timer interrupt process (FIG. 134) is interrupted and activated in the second interrupt period.

In this embodiment, in the process (step SB101 to step SB122) at the start of supplying the operating power, the interrupts of the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134) are basically prohibited. In the setting confirmation process (FIG. 166) and the setting value update process (FIG. 167), interruption is permitted. Therefore, in the situation where the setting confirmation process (FIG. 166) and the set value update process (FIG. 167) are not executed in the process (step SB101 to step SB122) at the time of starting the supply of the operating power, the first timer interrupt process (FIG. 133) and the execution of the second timer interrupt processing (FIG. 134) are prohibited, and the setting confirmation processing (FIG. 166) or the set value updating processing (FIG. 167) is being executed, the first timer interrupt processing (FIG. 133). ) And the execution of the second timer interrupt process (FIG. 134) are permitted. However, in the situation where the setting confirmation process (FIG. 166) or the set value update process (FIG. 167) is being executed, since the start-up processing flag is set to “1”, the first timer interrupt processing (FIG. Even if 133) is activated, among the various processes of the first timer interrupt process (FIG. 133), the processes for performing power failure monitoring, updating various counters, and fraudulent monitoring are executed, while progressing the game. The first timer interrupt process (FIG. 133) is terminated without executing the process.

After that, the setting update display flag is set to "1" on condition that the setting update display flag provided in the specific control work area 221 is not set to "1" (step SB302). When the setting update display flag is set to "1", a positive determination is made in step S9003 of the second timer interrupt process (FIG. 134), and the setting process for the fifth display data buffer 275 during the setting update is performed. (Step S9004) is executed. The processing content of the setting processing for the fifth display data buffer 275 during the setting update is the same as that in the 45th embodiment. By executing the process, as shown in the explanatory view of FIG. 124(a), for example, a display indicating that the setting value of the pachinko machine 10 is being updated and selection as an update target of the pachinko machine 10 are made. The displayed set values are displayed on the first to fourth notification display devices 201 to 204.

After that, initial setting at the start is performed (step SB303). In the initial setting, the game stop flag provided in the work area 221 for specific control is cleared to "0". As for the game stop flag, when the power failure flag is not set to "1" because the power failure process was not properly performed at the previous power shutdown (step SB104: NO), the work area 221 for specific control and If the checksums do not match due to a change in the information storage state of at least one of the specific control stack areas 222 since the last power-off (step SB105: NO), or the setting reference area 341. This is a flag that is set to "1" in step SB119 of the main process (FIG. 165) when the set value corresponding to the information stored in is not in the normal range (step SB106: NO). When the game stop flag is set to "1", the processes of steps S8901 to S8905 are executed in the first timer interrupt process (FIG. 133), while the positive determination is made in step S8906 to steps S8907 to step. The process of S8920 is not executed. As a result, when the information abnormality of the main RAM 65 as described above occurs, the processing for performing the power failure monitoring, the updating of various counters and the illegality monitoring is executed, while the processing for advancing the game is executed. Will not be done. By clearing the game stop flag to "0" in the process of step SB303, the state where the occurrence of the information abnormality of the main RAM 65 is specified is canceled when the set value update process (FIG. 167) is executed. Is possible.

After that, "1" is set in the setting update area 342 (see FIG. 154) in the specific control work area 221 (step SB304). The setting update area 342 is a storage area for storing information on the setting value being updated in the setting value updating process (FIG. 167) as in the 45th embodiment. When the numerical information of “1” is stored in the setting update area 342, the set value of the update target (selection target or change target) is “setting 1”. When the numerical information of “2” is stored in the setting update area 342, the setting value to be updated is “setting 2”. When the numerical information of “3” is stored in the setting update area 342, the setting value to be updated is “setting 3”. When the numerical information of "4" is stored in the setting update area 342, the setting value to be updated is "setting 4". When the numerical information of "5" is stored in the setting update area 342, the setting value to be updated is "setting 5". When the numerical information of “6” is stored in the setting update area 342, the setting value to be updated is “setting 6”.

By setting "1" in the setting update area 342 in step SB304, the setting value to be updated becomes "setting 1". That is, in the present embodiment, the setting value to be updated becomes “setting 1” when the setting value updating process (FIG. 167) is started regardless of the current setting value of the pachinko machine 10.

After that, the update start command is transmitted to the voice emission control device 81 (step SB305). Upon receiving the update start command, the sound emission control device 81 displays an image showing that the setting value update processing (FIG. 167) is being executed, and an image for making it possible to recognize the operation content for changing the setting value. , And the display control device 82 so as to display an image for recognizing the operation content for ending the setting value update process (FIG. 167) on the symbol display device 41. This allows the manager of the game hall to recognize that the setting value is being changed, and the operation content and the setting value update process necessary to change the setting value (FIG. 167). It becomes possible for the manager of the game hall to recognize the operation content necessary for ending the game. In addition to or instead of the above-mentioned notification being performed by the symbol display device 41, at least one of the display light emitting unit 53 and the speaker unit 54 may be configured. Further, a configuration may be adopted in which an external output indicating that the set value update processing (FIG. 167) is being executed is performed to a device outside the pachinko machine 10, such as a game hall management computer.

Then, it is determined whether the setting value information stored in the setting update area 342 is any one of "1" to "6" (step SB306). If it is not any of "1" to "6" (step SB306: NO), "1" is set in the setting update area 342 (step SB307). As a result, the setting value to be updated becomes “setting 1”.

When an affirmative determination is made in step SB306 or the processing of step SB307 is executed, it is determined whether or not the setting key insertion unit 68a has switched from the ON state to the OFF state using the setting key (step SB308). Specifically, it is determined whether the reception state of the signal received from the detection sensor that detects the state of the setting key insertion unit 68a has changed from the reception state corresponding to the ON state to the reception state corresponding to the OFF state. To do. Therefore, the OFF state is maintained not only when the setting key inserting section 68a is maintained in the ON state, but also when the setting value updating process is started in the situation where the setting key inserting section 68a is in the OFF state. Also in this case, a negative determination is made in step SB308.

When a negative determination is made in step SB308, the value of the setting update area 342 is incremented by 1 on the condition that the reset button 68c is pressed (step SB309: YES) (step SB310). As a result, each time the reset button 68c is pressed once, the setting value is updated by one step. When the reset button 68c is not pressed (step SB309: NO) or when the value of the setting update area 342 is incremented by 1, the process returns to step SB306, but the setting update is performed in step SB306. When it is determined that the value of the use area 342 is 7 or more, “1” is set in the setting update area 342 in step SB307. As a result, when the reset button 68c is pressed once in the situation of "setting 6", the process returns to "setting 1".

When it is specified that the setting key insertion unit 68a has switched from the ON state to the OFF state (step SB308: YES), the setting reference area 341 is overwritten with the setting value information stored in the setting update area 342 ( Step SB311). As a result, the setting value information obtained as a result of the update in the setting value updating process this time (FIG. 167) is set in the setting reference area 341, and the setting value corresponding to the set information is the current state. It becomes the set value of the pachinko machine 10.

After that, the interruption is prohibited (step SB312). As a result, when the set value update process (FIG. 167) is terminated and the process returns to the process (step SB101 to step SB122) at the start of supply of operating power in the main process (FIG. 165), the first timer interrupt process (FIG. 133) and the interrupt of the second timer interrupt processing (FIG. 134) are prohibited.

After that, the second RAM clearing process is executed (step SB313). In the second RAM clearing process, as in the RAM clearing process (step SA416) in the forty-fifth embodiment, an area in which the setting value information indicating the setting state of the pachinko machine 10 is set in the work area 221 for specific control ( That is, except for the setting reference area 341), the work area 221 for the specific control is cleared to "0" and the initial setting is executed. As a result, the area indicating whether or not the winning/winning lottery mode is the high-probability mode is cleared to "0". The mode is a low probability mode. In addition, the game times are not being executed, the opening/closing execution mode is not being executed, and the general-purpose display unit 38a is not being variably displayed, and the general electric accessory 34a is in the closed state. It becomes a situation. Further, since the hold storage area 65a and the universal electric power reserve area 65c provided in the work area 221 for specific control are also cleared to "0", the reserved information for the special figure display section 37a is deleted and the general figure display section is deleted. The hold information for 38a is deleted. Further, the setting update display flag and the setting confirmation display flag provided in the specific control work area 221 are cleared to "0". In addition, the setting update area 342 provided in the specific control work area 221 is cleared to “0”. Further, the game stop flag provided in the work area 221 for specific control is cleared to "0". In the second RAM clearing process, the stack area 222 for specific control is cleared to "0" and the initial setting is executed. In the second RAM clearing process, various registers of the main CPU 63 are cleared to "0" and then the initial setting is executed. In this initial setting, the same processing as the internal function register setting processing in step SB102 is executed. The process for clearing “0” and the process for initial setting are not executed for the work area 223 for non-specific control and the stack area 224 for non-specific control.

After that, a return command at the time of updating is transmitted to the voice emission control device 81 (step SB314). By receiving the return command at the time of updating, the sound emission control device 81 specifies that the main CPU 63 has completed the process (step SB101 to step SB122) at the time of starting the supply of the operating power, and at the same time, outputs the operating power of this time. It is specified that the setting value update processing (FIG. 167) has been executed in the processing at the start of supply (steps SB101 to SB122). Then, the processing corresponding to the reception of the update return command is executed. The contents of the processing will be described later.

Based on not only performing the power ON operation of the pachinko machine 10 while pressing the reset button 68c as described above, but also performing the power ON operation of the pachinko machine 10 while further operating the setting key insertion portion 68a by the setting key. The set value update process (FIG. 167) is executed. Further, as described above, the setting confirmation process (FIG. 166) is performed based on the power-on operation of the pachinko machine 10 while the setting key insertion portion 68a is turned on by the setting key without pressing the reset button 68c. Executed. As a result, it becomes possible to make the ON operation for the setting key insertion unit 68a common as the operation for executing the setting related processing regarding the setting value. Therefore, it becomes possible for the manager of the game hall to easily understand the operation content for generating the setting-related processing.

Further, when the power of the pachinko machine 10 is turned on while the setting key insertion section 68a is turned on by the setting key, and the pressing operation of the reset button 68c is not added, the setting confirmation process (FIG. 166) is performed. When the reset button 68c is pressed, the set value updating process (FIG. 167) is executed. As a result, it becomes possible to make the target process of the setting confirmation process (FIG. 166) and the setting value update process (FIG. 167) different depending on whether the reset button 68c is pressed. Therefore, it becomes possible for the manager of the game hall to easily understand the operation content for executing the desired processing of the setting confirmation processing (FIG. 166) and the setting value update processing (FIG. 167). Further, by making the operation contents for executing the setting value update process (FIG. 167) larger than the setting confirmation process (FIG. 166), the action for making the setting value update process (FIG. 167) illegal is performed. It is possible to make it difficult.

Returning to the explanation of the main processing (FIG. 165), when it is determined in step SB108 that the reset button 68c has been pressed, the setting key inserting section 68a has not been turned on using the setting key. When it is determined (step SB114: NO), it is determined whether or not "1" is set in the game stop flag in the work area 221 for specific control (step SB116). The game stop flag is a flag that is set to "1" when "1" is not set in the power failure flag, when the checksums do not match, or when the set value is abnormal. When the game stop flag is set to "1", the processes of steps S8901 to S8905 are executed in the first timer interrupt process (FIG. 133), while the positive determination is made in step S8906 to steps S8907 to step. The process of S8920 is not executed. As a result, when the power failure flag is not set to “1” because the power failure process was not properly performed at the previous power shutdown, the work area 221 for the specific control and the stack area 222 for the specific control are If at least one of the checksums does not match due to the change in the information storage state since the last power-off, or if the set value is abnormal, power failure monitoring, updating of various counters and illegal operation While the processing for monitoring is executed, the processing for advancing the game is not executed.

When "1" is not set in the game stop flag (step SB116: NO), the first RAM clearing process is executed (step SB117). In the first RAM clearing process, as in the RAM clearing process (step SA416) in the forty-fifth embodiment, an area in which the setting value information indicating the setting state of the pachinko machine 10 is set in the work area 221 for specific control ( That is, except for the setting reference area 341), the work area 221 for the specific control is cleared to "0" and the initial setting is executed. As a result, the area indicating whether or not the winning/winning lottery mode is the high-probability mode is cleared to "0". The mode is a low probability mode. In addition, the game times are not being executed, the opening/closing execution mode is not being executed, and the general-purpose display unit 38a is not being variably displayed, and the general electric accessory 34a is in the closed state. It becomes a situation. Further, since the hold storage area 65a and the universal electric power reserve area 65c provided in the work area 221 for specific control are also cleared to "0", the reserved information for the special figure display section 37a is deleted and the general figure display section is deleted. The hold information for 38a is deleted. Further, the setting update display flag and the setting confirmation display flag provided in the specific control work area 221 are cleared to "0". In addition, the setting update area 342 provided in the specific control work area 221 is cleared to “0”. In the first RAM clearing process, the stack area 222 for specific control is cleared to "0" and the initial setting is executed. Further, in the first RAM clearing process, various registers of the main CPU 63 are also cleared to “0” and then the initial setting is executed. In this initial setting, the same processing as the internal function register setting processing in step SB102 is executed.

The process for clearing “0” and the process for initial setting are not executed for the work area 223 for non-specific control and the stack area 224 for non-specific control. The processing contents of the first RAM clearing process (step SB117) are the same as the processing contents of the second RAM clearing process (step SB313) in the set value updating process (FIG. 167), but some of these processing contents are different. It may be configured to have. For example, in the first RAM clearing process (step SB117), the area targeted for “0” clearing and initial setting may not be the target for “0” clearing and initializing setting in the second RAM clearing process (step SB313). In the second RAM clearing process (step SB313), the area targeted for "0" clearing and initial setting may not be the target for "0" clearing and initial setting in the first RAM clearing process (step SB117).

After that, a return command at the time of clear is transmitted to the voice emission control device 81 (step SB118). By receiving the return command at the time of clearing, the sound emission control device 81 specifies that the processing at the start of supplying the operating power (step SB101 to step SB122) has ended in the main CPU 63, and the operating power It is specified that the first RAM clearing process (step SB117) has been executed in the process at the start of supply (steps SB101 to SB122). Then, the processing corresponding to the reception of the clear return command is executed. The contents of the processing will be described later.

In the main process (FIG. 165), when a negative determination is made in any of steps SB104 to SB106, that is, when the power failure flag is not set to "1", the checksums do not match, or the set value is abnormal. If it is, the game stop flag in the specific control work area 221 is set to "1" (step SB119). As described above, by setting the game stop flag to "1", the processes of steps S8901 to S8905 are executed in the first timer interrupt process (FIG. 133), while the positive determination is made in step S8906. The processes of steps S8907 to S8920 are not executed. As a result, when the power failure flag is not set to “1” because the power failure process was not properly performed at the previous power shutdown, the work area 221 for the specific control and the stack area 222 for the specific control are If at least one of the checksums does not match due to the change in the information storage state since the last power-off, or if the set value is abnormal, power failure monitoring, updating of various counters and illegal operation While the processing for monitoring is executed, the processing for advancing the game is not executed.

Then, it is determined whether or not the reset button 68c has been pressed (step SB120). When the reset button 68c is not pressed (step SB120: NO), an abnormal command indicating that an abnormality has occurred with respect to the power failure flag, the checksum, or the set value at the start of supplying the operating power is transmitted to the sound emission control device 81. Yes (step SB121). Upon receiving the abnormal command, the sound emission control device 81 causes the display light emitting unit 53 to emit light in a manner corresponding to the information abnormality at the time of starting the supply of the operating power, and the speaker unit 54 "Please change the setting." Is output. Moreover, the character image "Please change the setting." is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are ended when the supply of operating power to the pachinko machine 10 is stopped. However, even if the supply of the operating power to the pachinko machine 10 is temporarily stopped, the above notification is given when the supply of the operating power to the pachinko machine 10 is restarted until the setting value update processing (FIG. 167) is executed. It will be started again.

Then, the external output process at the time of abnormality is executed (step SB122). In the external output process at the time of abnormality, a process for externally outputting an abnormality signal to the management computer of the game hall is executed. In this case, the signal output of the abnormal signal is performed over a predetermined period (for example, 100 milliseconds). However, the present invention is not limited to this, and under the condition that the game stop flag is set to "1", the signal output of the abnormal signal is continued, and the game stop flag is cleared to "0", thereby indicating the abnormal signal. The signal output may be stopped. The abnormality signal can also be output when an abnormality different from the abnormality regarding the power failure flag, the checksum, and the set value occurs. For example, in the fraud detection process (step S8905) of the first timer interrupt process (FIG. 133), even when it is specified that a fraud of the monitoring target (illegal radio wave detection or fraudulent magnetism detection) occurs, the abnormal signal is generated It is output externally. However, the configuration is not limited to such a configuration in which an abnormality signal is also used, and a configuration in which an abnormality signal dedicated to an abnormality related to a power failure flag, checksum, or set value may be externally output may be used. It is also possible to have a configuration in which an abnormality signal corresponding to each of the abnormality regarding the check, the abnormality regarding the checksum, and the abnormality regarding the set value is externally output.

When the reset button 68c is pressed (step SB120: YES), it is determined whether or not the setting key insertion unit 68a is turned on by using the setting key (step SB114). When the reset button 68c is pressed and the setting key insertion portion 68a is turned on using the setting key (steps SB114 and SB120: YES), the set value updating process is executed (step SB115). The processing content of the setting value update processing is as already described. That is, when the operating power is supplied to the main CPU 63 while the "setting change operation" is being performed, an abnormality has occurred in the main RAM 65, and thus the result is negative in any of steps SB104 to SB106. Even if the determination is made, the set value updating process (FIG. 167) is executed. Thereby, it becomes possible to give priority to the change of the set value. Further, in the set value update processing (FIG. 167), the game stop flag is cleared to “0” by executing the initial setting at the start in step SB303 as already described. As a result, when the set value update process (FIG. 167) is executed, it is possible to eliminate the state in which the main RAM 65 has an abnormality after the set value update is completed.

On the other hand, when the reset button 68c is pressed but the setting key insertion part 68a is not turned on (step SB120: YES, step SB114: NO), the game stop flag in the work area 221 for specific control is set to "1". Is set (step SB116). In the process of step SB116 after the game stop flag is set to "1" in step SB119, since the game stop flag is set to "1" as a matter of course, a positive determination is made in step SB116. In this case, an abnormal command is transmitted to the sound emission control device 81 in step SB121, and an abnormal signal is externally output in step SB122.

That is, when an abnormality related to the power failure flag, the checksum, and the set value occurs and a negative determination is made in any of steps SB104 to SB106, the operation to the main CPU 63 is performed in the state where the "RAM clear operation" is performed. The first RAM clearing process (step SB117) is not executed even if the power supply is started. The first RAM clearing process is also performed when the supply of operating power to the main CPU 63 is started in the situation where the game stop flag is set to "1" and the "RAM clear operation" is being performed. (Step SB117) is not executed. As a result, even if the supply of operating power to the main CPU 63 is started while the "RAM clear operation" is being performed, the state in which the game stop flag is set to "1" can be prevented from being resolved. It will be possible. On the other hand, when the "setting change operation" is performed, the setting value update processing (FIG. 167) is executed and the setting is performed regardless of whether the game stop flag is set to "1" or not. The game stop flag is cleared to "0" in the initial setting (step SB303) at the start of the value updating process (Fig. 167). As a result, it becomes necessary to execute the set value update processing (FIG. 167) in order to cancel the state in which the game stop flag is set to "1". Therefore, when the information abnormality of the work area 221 for specific control occurs, not only the process for initializing the work area 221 for specific control, but also the resetting of the set value can be required. ..

Further, when the supply of operating power to the main CPU 63 is started in a situation where the game stop flag is set to "1", when "setting change operation" is not performed, that is, "no operation" In case of “RAM clear operation” or “setting confirmation operation”, an affirmative judgment is made in step SB109 or step SB116, so that an abnormal command is transmitted in step SB121 and an abnormality is detected in step SB122. The external output processing of is executed. As a result, when the game stop flag is set to "1", regardless of the processing results of step SB104 to step SB106 in the subsequent main processing, unless the set value update processing (FIG. 167) is executed, the main side Every time the supply of operating power to the CPU 63 is started, an abnormality notification in the pachinko machine 10 and an external output at the time of abnormality to the outside of the pachinko machine 10 are performed. Therefore, it becomes possible to let the manager of the game hall recognize that the set value should be changed.

When the process of step SB112 is executed, the process of step SB113 is executed, the process of step SB115 is executed, the process of step SB118 is executed, or the process of step SB122 is executed, Information corresponding to the initial check period (specifically, 5 seconds) is set in the checking counter provided in the work area 221 (step SB123). The value set in the checking counter is decremented by 1 each time the second timer interrupt process (FIG. 134) is activated, as in the 35th embodiment. When the value of 1 or more is set in the checking counter, the check display is continued on the first to fourth notification display devices 201 to 204 as in the 35th embodiment.

According to the above configuration, when the supply of the operating power to the main CPU 63 is started, the residual processing is performed after the processing at the start of the supply of the operating power (steps SB101 to SB122) is completed in the main CPU 63. Before (Step SB125 to Step SB128) is started, the initial check period is started. Accordingly, since it is not necessary to control the initial check period in the situation where the processing at the start of supplying the operating power is executed, the processing load in the situation where the processing at the start of supplying the operating power is executed is reduced. It becomes possible.

Further, while the setting confirmation process (FIG. 166) and the setting value update process (FIG. 167) are executed as the process at the start of supplying the operating power (step SB101 to step SB122), the initial check period is the operating power. The process is started after the process at the start of the supply of is completed. Accordingly, even if the check display is performed on the first to fourth notification display devices 201 to 204 during the initial check period, the set values are displayed using the first to fourth notification display devices 201 to 204. It becomes possible not to affect.

After that, the start-up processing flag in the specific control work area 221 is cleared to "0" (step SB124). When the first timer interrupt process (FIG. 133) is started by clearing the start-up processing flag “0”, a negative determination is made in step S8906, and thus not only the processes of steps S8901 to S8905 The processing of steps S8907 to S8920 will be executed, and the state where the processing for advancing the game is not executed is released. In step SB124, the power failure flag in the work area 221 for specific control is also cleared to "0".

After that, the process proceeds to the residual process of steps SB125 to SB128. In other words, the main CPU 63 is configured to periodically execute the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134), but between the one timer interrupt process and the next timer interrupt process. There will be some residual time. This remaining time will vary depending on the processing completion time of each timer interrupt processing, but the remaining processing of steps SB125 to SB128 is repeatedly executed by utilizing this irregular time. In this respect, it can be said that the residual process of steps SB125 to SB128 is an irregular process that is irregularly executed. In steps SB125 to SB128, the same processes as steps S113 to S116 of the main process (FIG. 9) in the first embodiment are executed.

Next, the interrupts of the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134) are permitted in the situation where the process at the start of supplying the operating power (step SB101 to step SB122) is being executed. The situation will be described with reference to the time chart of FIG. 168. FIG. 168(a) shows a period during which the power of the pachinko machine 10 is in an ON state, and FIG. 168(b) shows a period during which the process (step SB101 to step SB122) at the start of supply of operating power is executed. 168(c) shows a period in which the start-up processing flag in the work area 221 for specific control is set to "1", and FIG. 168(d) shows the residual processing (step SB125 to step SB128). 168(e) shows the period during which interrupts are permitted, and FIG. 168(f) shows the first timer interrupt process (FIG. 133) or the second timer interrupt process (FIG. 134). 168(g) shows the period during which the setting value update process (FIG. 167) is being executed, and FIG. 168(h) shows the setting confirmation process (FIG. 166). Indicates the period.

First, a case where neither the setting confirmation process (FIG. 166) nor the set value updating process (FIG. 167) is executed in the process (steps SB101 to SB122) at the start of supply of operating power will be described.

At a timing of t1, as shown in FIG. 168(a), the power of the pachinko machine 10 is turned on. In this case, the power-on operation of the pachinko machine 10 is performed in a situation of "no operation" in which none of the "RAM clear operation", the "setting change operation", and the "setting confirmation operation" are performed. At the timing of t1, as shown in FIG. 168(b), the main CPU 63 starts the process (step SB101 to step SB122) at the start of supplying the operating power. Further, as shown in FIG. 168(c), the start-up processing flag in the specific control work area 221 is set to "1".

After that, at the timing of t2, the process at the time of starting the supply of the operating power (steps SB101 to SB122) is finished as shown in FIG. 168(b), and the residual process (step SB125 is shown as shown in FIG. 168(d). ~Step SB128) is started. Further, at the timing of t2, the start-up processing flag in the specific control work area 221 is cleared to "0" as shown in FIG. 168(c). At the timing when the residual process (step SB125 to step SB128) is started, the interrupt is not permitted as shown in FIG. 168(e).

After that, at the timing of t3, the residual processing (step SB125 to step SB128) is completed as shown in FIG. 168(d), and the interrupt is permitted as shown in FIG. 168(e). This starts the timer interrupt processing as shown in FIG. 168(f). In this case, the second timer interrupt process (FIG. 134) is executed first, and the first timer interrupt process (FIG. 133) is executed when the second timer interrupt process (FIG. 134) ends. However, the present invention is not limited to this, and when the first timer interrupt process (FIG. 133) is executed first and the first timer interrupt process (FIG. 133) ends, the second timer interrupt process (FIG. 134) is executed. It may be configured to be executed.

Next, a case will be described in which the set value update process (FIG. 167) is executed in the process (step SB101 to step SB122) at the start of supplying the operating power.

At timing t4, the pachinko machine 10 is turned on as shown in FIG. 168(a). In this case, the power-on operation of the pachinko machine 10 is performed in the situation where the “setting change operation” is performed. At the timing of t4, as shown in FIG. 168(b), the main CPU 63 starts the process (step SB101 to step SB122) at the start of supplying the operating power. Further, as shown in FIG. 168(c), the start-up processing flag in the specific control work area 221 is set to "1".

Thereafter, at the timing of t5, the set value update processing (FIG. 167) is started as shown in FIG. 168(g). In this case, the interrupt is permitted at the timing of t5 as shown in FIG. 168(e). When the interrupt is permitted, the timer interrupt process is started at the timing of t6 as shown in FIG. 168(f). In this case, the second timer interrupt process (FIG. 134) is executed first, and the first timer interrupt process (FIG. 133) is executed when the second timer interrupt process (FIG. 134) ends. However, the present invention is not limited to this, and when the first timer interrupt process (FIG. 133) is executed first and the first timer interrupt process (FIG. 133) ends, the second timer interrupt process (FIG. 134) is executed. It may be configured to be executed. Even if the first timer interrupt process (FIG. 133) is executed, since the start-up processing flag is set to “1” as shown in FIG. 168(c), power failure monitoring, updating of various counters, and While processing for performing fraud monitoring is executed, processing for advancing the game is not executed.

The timer interrupt process ends at the timing of t7 as shown in FIG. 168(f), and then the set value updating process (FIG. 167) as shown in FIG. 168(g) ends at the timing of t8. Then, at the timing of t8, as shown in FIG. 168(b), the process at the start of supplying the operating power (steps SB101 to SB122) is completed, and the start-up flag is set as shown in FIG. 168(c). "0" is cleared. Further, at the timing of t8, the residual process (step SB125 to step SB128) is started as shown in FIG. 168(d).

Next, a case where the setting confirmation process (FIG. 166) is executed in the process (step SB101 to step SB122) at the start of supplying the operating power will be described.

At timing t9, the pachinko machine 10 is turned on as shown in FIG. 168(a). In this case, the power-on operation of the pachinko machine 10 is performed while the “setting confirmation operation” is performed. At the timing of t9, as shown in FIG. 168(b), the main CPU 63 starts the process at the start of supplying the operating power (steps SB101 to SB122). Further, as shown in FIG. 168(c), the start-up processing flag in the specific control work area 221 is set to "1".

After that, at the timing of t10, the setting confirmation process (FIG. 166) is started as shown in FIG. 168(h). In this case, the interrupt is permitted at the timing of t10 as shown in FIG. 168(e). When the interrupt is permitted, the timer interrupt process is started at the timing of t11 as shown in FIG. 168(f). In this case, the second timer interrupt process (FIG. 134) is executed first, and the first timer interrupt process (FIG. 133) is executed when the second timer interrupt process (FIG. 134) ends. However, the present invention is not limited to this, and when the first timer interrupt process (FIG. 133) is executed first and the first timer interrupt process (FIG. 133) ends, the second timer interrupt process (FIG. 134) is executed. It may be configured to be executed. Even if the first timer interrupt process (FIG. 133) is executed, since the start-up processing flag is set to “1” as shown in FIG. 168(c), power failure monitoring, updating of various counters, and While processing for performing fraud monitoring is executed, processing for advancing the game is not executed.

The timer interrupt process ends at timing t12 as shown in FIG. 168(f), and then the setting confirmation process (FIG. 166) as shown in FIG. 168(h) ends at timing t13. Then, at the timing of t13, as shown in FIG. 168(b), the process at the start of supplying the operating power (steps SB101 to SB122) is completed, and the start-up flag is set as shown in FIG. 168(c). "0" is cleared. Further, at the timing of t13, the residual processing (step SB125 to step SB128) is started as shown in FIG. 168(d).

As described above, the first timer interrupt process (in the situation where the setting confirmation process (FIG. 166) and the set value update process (FIG. 167) are not executed in the process (step SB101 to step SB122) at the start of supply of the operating power) 133) and the execution of the second timer interrupt process (FIG. 134) are prohibited, and the setting confirmation process (FIG. 166) or the set value update process (FIG. 167) is being executed, the first timer interrupt process (FIG. 133) and the execution of the second timer interrupt processing (FIG. 134) are permitted. If the setting confirmation process (FIG. 166) and the set value update process (FIG. 167) are not executed, the timer interrupt process is not interrupted and activated during the process (step SB101 to step SB122) at the start of supplying the operating power. By doing so, it becomes possible to complete the processing (step SB101 to step SB122) at the start of supplying the operating power at an early stage.

On the other hand, when the setting confirmation process (FIG. 166) and the setting value update process (FIG. 167) are executed, the process according to the operation of the manager of the game hall is executed. Becomes longer. In this case, even if the setting confirmation process (FIG. 166) and the set value update process (FIG. 167) are being executed, assuming that the interrupt of the timer interrupt process remains disabled, the execution of the timer interrupt process starts. The timing is extremely late. On the other hand, when the setting confirmation process (FIG. 166) or the set value update process (FIG. 167) is executed, the interrupt of the timer interrupt process is permitted. This makes it possible to prevent the execution start timing of the timer interrupt processing from being extremely delayed. Further, in a situation where the setting confirmation process (FIG. 166) and the setting value update process (FIG. 167) are being executed, the process for display control of the first to fourth notification display devices 201 to 204 is executed. When the second timer interrupt process (FIG. 134) is executed by interruption, the second timer interrupt process (FIG. 134) is used to display the set values on the first to fourth notification display devices 201 to 204. It is possible to do it.

Further, in the situation where the setting confirmation process (FIG. 166) or the set value update process (FIG. 167) is being executed, “1” is set in the startup processing flag. Therefore, even if the first timer interrupt process (FIG. 133) is activated in the situation where the setting confirmation process (FIG. 166) or the set value update process (FIG. 167) is being executed, the first timer interrupt process (FIG. It is possible to prevent the processing for advancing the game from being executed while the processing for performing power failure monitoring, updating various counters, and fraudulent monitoring among various processing of 133) is executed.

Next, the manner in which the processing proceeds when an abnormality related to the power failure flag, checksum, or set value occurs will be described with reference to the time chart in FIG. 169. FIG. 169(a) shows a period during which the power of the pachinko machine 10 is in an ON state, and FIG. 169(b) shows a period during which the process (step SB101 to step SB122) at the start of supply of operating power is executed. 169(c) shows the period during which the residual processing (step SB125 to step SB128) is executed, and FIG. 169(d) shows the first timer interrupt processing (FIG. 133) or the second timer interrupt processing (FIG. 134). 169) indicates a period during which the game stop flag in the work area 221 for specific control is set to "1", and FIG. 169(f) indicates that an abnormal signal is external. 169(g) shows the period during which the set value updating process (FIG. 167) is being executed.

At a timing of t1, the pachinko machine 10 is turned on as shown in FIG. 169(a). In this case, the power-on operation of the pachinko machine 10 is performed in a situation of "no operation" in which none of the "RAM clear operation", the "setting change operation", and the "setting confirmation operation" are performed. At the timing of t1, as shown in FIG. 168(b), the main CPU 63 starts the process (step SB101 to step SB122) at the start of supplying the operating power.

After that, at the timing of t2, the occurrence of an abnormality relating to any one of the power failure flag, the checksum, and the set value is specified, so that the game stop flag in the work area 221 for specific control is set to "" as shown in FIG. 169(e). 1” is set. Further, at the timing of t2, the external output of the abnormal signal is started as shown in FIG. 169(f). As a result, it becomes possible for the management computer in the game hall to specify that an abnormality related to any of the power failure flag, the checksum, and the set value has occurred in the pachinko machine 10.

After that, at the timing of t3, the process at the start of the supply of the operating power (steps SB101 to SB122) ends as shown in FIG. 169(b), and the residual process (steps SB125 to step SB125 to step SB125 as shown in FIG. 169(c). SB128) is started. Further, at the timing of t4, the external output of the abnormal signal is ended as shown in FIG. 169(f). The external output of the abnormal signal is continued for a predetermined period (for example, 100 milliseconds) from the timing of t2 to the timing of t4, so that the pachinko machine 10 has an abnormality regarding one of the power failure flag, the checksum, and the set value. It is possible to accurately specify what has been done in the management computer of the game hall. Further, since the period during which the external output of the abnormal signal is continued is constant for a predetermined period, it is possible to simplify the processing configuration for performing the external output of the abnormal signal. In addition to the external output of the abnormality signal, abnormality notification in the symbol display device 41, the display light emitting unit 53, and the speaker unit 54 is also executed.

After that, at the timing of t5, the residual process (step SB125 to step SB128) ends as shown in FIG. 169(c). Then, the timer interrupt process is executed as shown in FIG. 169(d) from the timing of t5 to the timing of t6, and the residual process as shown in FIG. 169(c) from the timing of t6 to the timing of t7 ( Steps SB125 to SB128) are executed, and the timer interrupt processing is executed from timing t7 to timing t8 as shown in FIG. 169(d). However, since "1" is set in the game stop flag as shown in FIG. 169(e), even if the first timer interrupt processing (FIG. 133) is executed, power failure monitoring, updating of various counters, and illegality Although the processing for monitoring is executed, the processing for advancing the game is not executed. At the timing of t8, the power failure process is executed by the first timer interrupt process (FIG. 133), and the power of the pachinko machine 10 is turned off as shown in FIG. 169(a).

After that, at the timing of t9, the power of the pachinko machine 10 is turned on again as shown in FIG. 169(a), and the process at the start of supplying the operating power as shown in FIG. 169(b) (steps SB101 to SB122). ) Is started. In this case, "1" is set to the game stop flag in the specific control work area 221 as shown in FIG. 169(e). Therefore, the abnormal signal is externally output as shown in FIG. 169(f) from the timing of t10 to the timing of t12. As a result, it becomes possible to make the management computer of the game hall recognize again that the pachinko machine 10 has an abnormality related to any of the power failure flag, the checksum, and the set value. In addition to the external output of the abnormality signal, abnormality notification in the symbol display device 41, the display light emitting unit 53, and the speaker unit 54 is also executed.

Further, as shown in FIG. 169(b), the process at the start of supplying the operating power (steps SB101 to SB122) ends at the timing of t11, and the processing from the timing of t11 to the timing of t13 is performed as shown in FIG. 169(c). The residual process (step SB125 to step SB128) is executed as shown in FIG. Then, as shown in FIG. 169(d), the timer interrupt process is executed at the timing of t13. However, since "1" is set in the game stop flag as shown in FIG. 169(e), even if the first timer interrupt processing (FIG. 133) is executed, power failure monitoring, updating of various counters, and illegality Although the processing for monitoring is executed, the processing for advancing the game is not executed. At the timing of t14, the power failure process is executed by the first timer interrupt process (FIG. 133), and the power of the pachinko machine 10 is turned off as shown in FIG. 169(a).

After that, at the timing of t15, the power of the pachinko machine 10 is turned on again as shown in FIG. 169(a), and the process at the start of supplying the operating power as shown in FIG. 169(b) (steps SB101 to SB122). ) Is started. Then, as shown in FIG. 169(g), the set value update processing (FIG. 167) is executed from the timing of t16 to the timing of t17. Not only is the setting value changed by executing the setting value updating process (FIG. 167), but the game stop flag in the specific control work area 221 is cleared to “0” as shown in FIG. 169(e). It As a result, the state in which the execution of the process for advancing the game is blocked due to the occurrence of the information abnormality of the work area 221 for specific control is eliminated. After that, the residual processing (steps SB125 to SB128) is executed as shown in FIG. 169(c) from the timing of t17 to the timing of t18, and the timer interrupt processing is performed at the timing of t18 as shown in FIG. 169(d). Is started.

As described above, when an abnormality related to the power failure flag, the checksum, and the set value occurs and a negative determination is made in any of steps SB104 to SB106 in the main processing (FIG. 165), the game in the work area 221 for specific control is played. By setting the stop flag to "1", the process for advancing the game is not executed. As a result, it becomes possible to prevent the game from being played even though the information abnormality of the work area 221 for specific control has occurred.

Also, the state in which the game stop flag is set to "1" cannot be resolved unless the set value updating process (Fig. 167) is executed. As a result, it becomes necessary to execute the set value update processing (FIG. 167) in order to cancel the state in which the game stop flag is set to "1", and the information abnormality in the work area 221 for specific control occurs. In that case, not only the processing for initializing the work area 221 for the specific control but also the resetting of the set value can be required.

Next, the display contents of the first to fourth notification display devices 201 to 204 when the supply of the operating power to the main CPU 63 is started will be described with reference to the time chart of FIG. FIG. 170(a) shows a period in which the process (step SB101 to step SB122) at the start of supplying the operating power is executed, and FIG. 170(b) shows the process at the start of supplying the operating power (step SB101 to step SB122). ) Shows the period during which the process is executed, FIG. 170(c) shows the initial check period, and FIG. 170(d) shows the period during which the set value update process (FIG. 167) is executed. 170(e) shows a display indicating that the setting value of the pachinko machine 10 is being updated and a display indicating the current setting value of the pachinko machine 10 is the first to fourth notification display devices 201 to 204. 170(f) shows the period during which the setting confirmation process (FIG. 166) is being executed, and FIG. 170(g) shows the set value of the pachinko machine 10. The display indicating that the pachinko machine 10 is in the current state and the display indicating the current setting value of the pachinko machine 10 indicate the setting confirmation display period performed on the first to fourth notification display devices 201 to 204.

First, a case where neither the setting confirmation process (FIG. 166) nor the set value updating process (FIG. 167) is executed in the process (steps SB101 to SB122) at the start of supply of operating power will be described.

As shown in FIG. 170(a), the processing at the start of the supply of the operating power (steps SB101 to SB122) is executed from the timing t1 to the timing t2. Then, at the timing of t2, as shown in FIG. 170(b), the process after the process at the start of supplying the operating power (steps SB101 to SB122) is finished is started. In this case, the initial check period is started by executing the setting process of the checking counter in step SB122 in the main process (FIG. 165) at the timing of t2. As a result, the check display is started on the first to fourth notification display devices 201 to 204 (see FIG. 128(b)). Since the process for advancing the game is executed even during the initial check period, the game can be performed in a situation where the check display is being displayed on the first to fourth notification display devices 201 to 204. .. After that, at the timing of t3, the initial check period ends as shown in FIG. 170(c). As a result, the display of the base value is started on the first to fourth notification display devices 201 to 204.

Next, a case will be described in which the set value update process (FIG. 167) is executed in the process (step SB101 to step SB122) at the start of supplying the operating power.

At the timing of t4, as shown in FIG. 170(a), the process at the start of supplying the operating power (steps SB101 to SB122) is started. Then, the set value update processing (FIG. 167) is executed from timing t5 to timing t6 as shown in FIG. 170(d). In this case, as shown in FIG. 170(e), the setting update display period is from the timing t5 to the timing t6.

After that, at the timing of t6, as shown in FIG. 170(b), the process after the process at the start of supplying the operating power (steps SB101 to SB122) is finished is started. In this case, the initial check period is started by executing the setting process of the checking counter in step SB122 in the main process (FIG. 165) at the timing of t6. As a result, the check display is started on the first to fourth notification display devices 201 to 204 (see FIG. 128(b)). Since the process for advancing the game is executed even during the initial check period, the game can be performed in a situation where the check display is being displayed on the first to fourth notification display devices 201 to 204. .. Thereafter, at the timing of t7, the initial check period ends as shown in FIG. 170(c). As a result, the display of the base value is started on the first to fourth notification display devices 201 to 204.

Next, a case where the setting confirmation process (FIG. 166) is executed in the process (step SB101 to step SB122) at the start of supplying the operating power will be described.

As shown in FIG. 170(a), the processing at the start of supplying the operating power (steps SB101 to SB122) is started at the timing of t8. Then, the setting confirmation process (FIG. 166) is executed from timing t9 to timing t10 as shown in FIG. 170(f). In this case, as shown in FIG. 170(g), the setting confirming display period extends from the timing t9 to the timing t10.

After that, at the timing of t10, as shown in FIG. 170(b), the process after the process at the start of supplying the operating power (steps SB101 to SB122) is finished is started. In this case, the initial check period is started by executing the setting process of the checking counter in step SB122 of the main process (FIG. 165) at the timing of t10. As a result, the check display is started on the first to fourth notification display devices 201 to 204 (see FIG. 128(b)). Since the process for advancing the game is executed even during the initial check period, the game can be performed in a situation where the check display is being displayed on the first to fourth notification display devices 201 to 204. .. Then, at the timing of t11, the initial check period ends as shown in FIG. 170(c). As a result, the display of the base value is started on the first to fourth notification display devices 201 to 204.

According to the above configuration, when the supply of the operating power to the main CPU 63 is started, the residual processing is performed after the processing at the start of the supply of the operating power (steps SB101 to SB122) is completed in the main CPU 63. Before (Step SB125 to Step SB128) is started, the initial check period is started. Accordingly, since it is not necessary to control the initial check period in the situation where the processing at the start of supplying the operating power is executed, the processing load in the situation where the processing at the start of supplying the operating power is executed is reduced. It becomes possible.

Further, while the setting confirmation process (FIG. 166) and the setting value update process (FIG. 167) are executed as the process at the start of supplying the operating power (step SB101 to step SB122), the initial check period is the operating power. The process is started after the process at the start of the supply of is completed. Accordingly, even if the check display is performed on the first to fourth notification display devices 201 to 204 during the initial check period, the set values are displayed using the first to fourth notification display devices 201 to 204. It becomes possible not to affect.

Next, when the power outage process is executed in the situation where the set value update process (FIG. 167) or the setting confirmation process (FIG. 166) is executed, the main process (Fig. The contents of the processing executed in (165) will be described with reference to the explanatory diagram of FIG.

When neither the set value update process (FIG. 167) nor the setting confirmation process (FIG. 166) is executed and the power failure process is executed, the main process (FIG. The contents of the process executed in () will be described first.

When the supply of operating power is restarted in the "no operation" situation, the first RAM clearing process (step SB117), the set value updating process (Fig. 167) and the setting confirming process (Fig. 166) are executed in the main process (Fig. 165). ) Is not executed. When the supply of operating power is restarted in the state where the “RAM clear operation” is performed, the first RAM clear process (step SB117) is executed in the main process (FIG. 165), while the set value update process ( 167) and the setting confirmation process (FIG. 166) are not executed. When the supply of operating power is restarted in the situation where the “setting change operation” is performed, the set value update processing (FIG. 167) is executed in the main processing (FIG. 165), while the first RAM clear processing (step SB117) is executed. ) And the setting confirmation process (FIG. 166) are not executed. When the supply of the operating power is restarted in the situation where the “setting confirmation operation” is performed, the main processing (FIG. 165) executes the setting confirmation processing (FIG. 166) while the first RAM clear processing (step SB117). ) And the set value update process (FIG. 167) are not executed.

Next, when the power outage process is executed in the situation where the setting value update process (FIG. 167) is being executed (that is, the condition where the setting update display flag is set to “1”), the subsequent supply of operating power is performed. The contents of the process executed in the main process (FIG. 165) when the process is restarted will be described.

If the operating power supply is restarted in the "no operation" situation, if the operating power supply is restarted in the "RAM clear operation" situation, the operation is performed in the "setting change operation" situation Whether the power supply is restarted or the operating power supply is restarted in the situation where the “setting confirmation operation” is performed, the main process (FIG. 165) does not perform the set value update process (FIG. 165). 167) is executed, but the setting confirmation process (FIG. 166) is not executed. That is, when the power outage process is executed in the situation where the set value update process (FIG. 167) is executed, the set value update is performed regardless of the operation content at the time of restarting the supply of the operating power thereafter. The process (FIG. 167) is newly started.

With the above configuration, when the supply of the operating power is stopped in the middle of the set value updating process (FIG. 167), when the supply of the operating power is restarted, the setting key insertion portion when the power of the pachinko machine 10 is turned on. It is possible to newly start the set value updating process (FIG. 167) regardless of the operation contents of the 68a and the reset button 68c. This makes it possible to surely generate an opportunity to complete the update of the set value. Therefore, it is possible to prevent the game from being started even though the setting value has not been updated.

Further, when the supply of operating power is stopped in the middle of the set value updating process (FIG. 167), the set value updating process (FIG. 167) is uniquely executed irrespective of the operation contents when restarting the supply of operating power. By doing so, it is possible to achieve the above-mentioned excellent effects while simplifying the processing configuration as compared with the configuration in which the processing content executed according to each operation content is changed.

Next, when the power failure process is executed in the situation where the setting confirmation process (FIG. 166) is being executed (that is, the condition where the setting confirmation display flag is set to “1”), the subsequent supply of operating power is performed. The contents of the process executed in the main process (FIG. 165) when the process is restarted will be described.

When the supply of operating power is restarted in the state where the "RAM clear operation" is performed, the main process (FIG. 165) executes the first RAM clear process (step SB117), while the set value update process (FIG. 167) is executed. The setting confirmation process (FIG. 166) is not executed. That is, even if the power failure process is executed in the situation where the setting confirmation process (FIG. 166) is being executed, the setting confirmation is performed when the “RAM clear operation” is performed when the supply of the operating power is resumed thereafter. The first RAM clearing process (step SB117) is executed without newly executing the use process (FIG. 166). This makes it possible to prioritize the execution of the first RAM clearing process (step SB117) for the “RAM clearing operation”. The setting confirmation display flag is cleared to "0" by executing the first RAM clearing process (step SB117).

When the supply of operating power is restarted in the situation where the “setting change operation” is performed, the setting value updating process (FIG. 167) is executed in the main process (FIG. 165), while the setting confirmation process (FIG. 166) is executed. Is not executed. That is, even if the power failure process is executed in the situation where the setting confirmation process (FIG. 166) is being executed, the setting confirmation is performed when the “setting change operation” is performed when the supply of the operating power is resumed thereafter. The setting value update process (FIG. 167) is executed without newly executing the use process (FIG. 166). As a result, it becomes possible to give priority to the execution of the setting value update processing (FIG. 167) for the “setting change operation”. Even if the setting confirmation process (FIG. 166) is not executed in this way, the setting value to be updated is displayed on the fourth notification display device 204 by the setting value update process (FIG. 167) being executed. At the end of the set value update process (FIG. 167) that is displayed, the information of the set value to be updated at that time is set in the setting reference area 341. The set value of 10 can be confirmed. The setting confirmation display flag is cleared to "0" by executing the second RAM clearing process (step SB313) in the setting value updating process (Fig. 167).

When the supply of operating power is restarted while the "setting check operation" is performed, the main process (Fig. 165) is used for setting check provided that no abnormality has occurred with respect to the power failure flag, checksum, and set value. The process (FIG. 166) is executed. As a result, even if the power failure process is executed in the middle of the setting confirmation process (FIG. 166), it is possible to restart the confirmation of the set value by performing the "setting confirmation operation" when the supply of the operating power is restarted. Becomes

When the supply of operating power is restarted in the “no operation” situation, the setting key insertion unit 68a operates on the condition that no abnormality has occurred in the power failure flag, the checksum, and the set value in the main process (FIG. 165). The setting confirmation process (FIG. 166) is executed even if the ON operation is not performed. As a result, even if the power failure process is executed in the middle of the setting confirmation process (FIG. 166) and the setting value is confirmed when the operation power supply is restarted after that, the operation is not performed. It becomes possible to restart.

Next, the processing executed by the sound emission control device 81 will be described. Prior to the description of the processing, the electrical configuration of the sound emission control device 81 will be described with reference to the explanatory diagram of FIG. 172.

The voice emission control device 81 includes a voice emission control board 351. The sound emission side MPU 352 is mounted on the sound emission control board 351. The sound-light side MPU 352 includes a sound-light side ROM 354 and a sound-light side RAM 355 in addition to the sound-light side CPU 353 which is an arithmetic processing unit including a control unit and a calculation unit. In addition to the above-described elements, the sound/light side MPU 352 has an interrupt circuit, a timer circuit, a data input/output circuit, various counter circuits as a random number generator, and the like built therein.

The sound-light side ROM 354 is a memory such as a NOR flash memory and a NAND flash memory that does not require external power supply for storage, and is used as a read-only memory. The sound-light side ROM 354 stores various control programs executed by the sound-light side CPU 353 and fixed value data.

The sound-light side RAM 355 is a memory (that is, a volatile storage means) such as an SRAM and a DRAM that needs to be supplied with electric power from the outside to retain the storage, and is used for both reading and writing. The sound-light side RAM 355 is capable of random access and has a shorter read time than the sound-light side ROM 354 when compared with the same data capacity. The sound-light side RAM 355 temporarily stores various data and the like for the execution of the control program stored in the sound-light side ROM 354.

An RTC 356 and an RTC memory 357 are mounted on the sound emission control board 351 in addition to the sound-light side MPU 352. The RTC 356 is a real-time clock that constantly measures date information and time information, and outputs the measured date information and time information (hereinafter also referred to as date and time information) according to an instruction from the sound-light side CPU 353. This is a configuration that can be performed. Note that the RTC 356 is provided with a backup power supply, and it is possible to measure date information and time information even while the pachinko machine 10 is powered off. Further, the RTC 356 is not limited to the configuration in which the date and time information is measured, and may have a configuration in which only the time information is measured.

The RTC memory 357 is a memory (that is, a volatile storage means) such as an SRAM and a DRAM that needs to be supplied with electric power from the outside to retain the storage, and is used for both reading and writing. The RTC memory 357 stores date and time information of the RTC 356 in accordance with an instruction from the sound-light side CPU 353. The date and time information stored in the RTC memory 357 is read by the sound-light side CPU 353 as necessary. The sound-light side CPU 353 grasps the reference time based on the date and time information stored in the RTC memory 357, and the time-corresponding effect is executed every time a predetermined time (for example, 1 hour) elapses with reference to the reference time. To execute the process. The RTC memory 357 is configured to be supplied with backup power from a backup power supply provided for the RTC 356, and the date and time information is stored and retained even while the pachinko machine 10 is powered off. However, the present invention is not limited to this, and the RTC memory 357 may be an EEPROM or the like that does not require external power supply to store and hold information.

Next, the effect control processing executed by the sound-light side CPU 353 will be described with reference to the flowchart in FIG. The effect control process is executed when the supply of operating power to the sound-light side CPU 353 is started.

When the update start command is received from the main CPU 63 (step SB401: YES), the update notification setting process is executed (step SB402). As described above, the update start command is transmitted to the sound-light side CPU 353 when the set value update processing (FIG. 167) is started by the main CPU 63. In the update notification setting process, an image showing that the set value update process (FIG. 167) is being executed, an image for making it possible to recognize the operation content for changing the set value, and the set value update process ( Display control of the display control device 82 is performed so that an image for making it possible to recognize the operation content for ending (FIG. 167) is displayed on the symbol display device 41. This allows the manager of the game hall to recognize that the setting value is being changed, and the operation content and the setting value update process necessary to change the setting value (FIG. 167). It becomes possible for the manager of the game hall to recognize the operation content necessary for ending the game. In addition to or instead of the above-mentioned notification being performed by the symbol display device 41, at least one of the display light emitting unit 53 and the speaker unit 54 may be configured.

When the confirmation start command is received from the main CPU 63 (step SB403: YES), the confirmation notification setting process is executed (step SB404). As described above, the confirmation start command is transmitted to the sound/light side CPU 353 when the setting confirmation process (FIG. 166) is started by the main side CPU 63. In the confirmation notification setting process, an image showing that the setting confirmation process (FIG. 166) is being executed and an image for making it possible to recognize the operation content for terminating the setting confirmation process (FIG. 166) are displayed. The display control device 82 controls the display so that it is displayed on the symbol display device 41. This allows the manager of the game hall to recognize that the current setting value of the pachinko machine 10 is being confirmed, and is necessary for ending the setting confirmation process (FIG. 166). It is possible for the manager of the game hall to recognize various operation contents. In addition to or instead of the above-mentioned notification being performed by the symbol display device 41, at least one of the display light emitting unit 53 and the speaker unit 54 may be configured.

When the processes of steps SB401 to SB404 are executed, it is determined whether any one of the normal restoration command, the clear restoration command, the confirmation restoration command, and the update restoration command is received from the main CPU 63 ( Step SB405). The normal return command is a process at the start of supply of operating power (step SB101) without executing the first RAM clear process (step SB117), the setting confirmation process (FIG. 166), and the set value update process (FIG. 167). ~ Sent when step SB122) is completed. The return command at the time of clearing is transmitted when the first RAM clearing process (step SB117) is executed and the process at the start of supplying the operating power (steps SB101 to SB122) is completed. The return command at the time of confirmation is transmitted when the setting confirmation process (FIG. 166) is executed and the process at the start of supplying the operating power (steps SB101 to SB122) is completed. The update return command is transmitted when the set value update process (FIG. 167) is executed and the process at the start of supplying the operating power (steps SB101 to SB122) is completed.

If these return commands have not been received (step SB405: NO), the process returns to step SB401. The main CPU 63 transmits one of the return commands to the sound/light side CPU 353 when the process at the start of supplying the operating power (step SB101 to step SB122) is completed. In this case, as described above, the sound-light side CPU 353 does not execute the processing from step SB406 until any one of the return commands is received from the main side CPU 63. As a result, while the main CPU 63 is executing the processing (step SB101 to step SB122) at the time of starting the supply of operating power, the sound/light side CPU 353 can be prevented from starting the execution control of the normal effect. It will be possible.

Further, in a situation where no return command has been received, there is a possibility that an update start command or a confirmation start command will be received from the main CPU 63, and when the update start command is received, the set value update processing has already been described. The notification corresponding to the execution of (FIG. 167) needs to be performed, and when the confirmation start command is received, the setting confirmation process (FIG. 166) is executed as described above. Corresponding notifications need to be made. In this case, the sound-light side CPU 353 does not execute the processing of step SB406 and subsequent steps until it receives any return command from the main side CPU 63, so that when the update start command or the confirmation start command is received, the corresponding notification Can be started appropriately.

When any return command is received from the main CPU 63 (step SB405: YES), it is determined whether the received return command is a normal return command (step SB406). As described above, the normal recovery command is executed when the supply of operating power is started without executing the first RAM clear process (step SB117), the setting confirmation process (FIG. 166), and the set value update process (FIG. 167). Is transmitted when the process (step SB101 to step SB122) is completed. When the normal recovery command is received (step SB406: YES), the current date and time information of the RTC 356 is read out and the read out date and time information is stored in the RTC memory 357 (step SB407). As a result, the RTC memory 357 stores the date and time information serving as a reference when specifying the timing for executing the time-based effect.

When the return command received this time is not the normal return command (step SB406: NO) but the update return command (step SB408: YES), update end notification processing is executed (step SB409). The return command at the time of updating is transmitted to the sound/light side CPU 353 when the setting value updating process (FIG. 167) is completed by the main side CPU 63 as already described. In the update notification end processing, the notification corresponding to the setting value update processing (FIG. 167) started in step SB402 is ended.

If the return command received this time is not the update return command (step SB408: NO) but the confirmation return command (step SB410: YES), the confirmation notification end process is executed (step SB411). As described above, the return command for confirmation is transmitted to the sound/light side CPU 353 when the setting confirmation process (FIG. 166) is completed in the main side CPU 63. In the confirmation notification ending process, the notification corresponding to the setting confirmation process (FIG. 166) started in step SB404 is ended.

When the process of step SB407 is executed, the process of step SB409 is executed, the negative determination is made in step SB410, or the process of step SB411 is executed, a process for executing execution control of a normal effect is performed. Execute. Specifically, first, it is determined whether or not it is the start timing of the time-corresponding effect (step SB412).

The time-corresponding effect is an effect that is executed every time a predetermined time (for example, one hour) elapses with reference to the reference time corresponding to the date and time information stored in the RTC memory 357. In the time corresponding effect, the display light emitting unit 53 performs a light emitting effect corresponding to the time corresponding effect, the speaker unit 54 performs a sound output effect corresponding to the time corresponding effect, and the symbol display device 41 corresponds to the time corresponding effect. Display effect is performed.

When the time corresponding effect is started in the situation where the game turning effect is being executed, the display light emitting unit 53 and the speaker unit 54 preferentially execute the time corresponding effect over the game turning effect. On the other hand, in the symbol display device 41, the image display corresponding to the time-corresponding effect is performed in a state where the image display corresponding to the effect for game use is reduced and displayed on a part of the display surface of the symbol display device 41. In addition, when the time-corresponding effect is started in the situation where the effect for the opening/closing execution mode is being executed, the time-corresponding effect is preferentially executed in the display light emitting unit 53 and the speaker unit 54 over the effect for the opening/closing execution mode. On the other hand, in the symbol display device 41, the image display corresponding to the time-corresponding effect is performed in a state where the image display corresponding to the effect for the opening/closing execution mode is reduced and displayed on a part of the display surface of the symbol display device 41.

With the configuration in which the time-corresponding effect is executed every time a predetermined time (for example, one hour) elapses with reference to the reference time corresponding to the date and time information stored in the RTC memory 357, a plurality of adjacent game halls are provided. If the reference times of the pachinko machines 10 are the same, it is possible to simultaneously start the time-corresponding effects on the plurality of pachinko machines 10. In the game hall, since the power of a plurality of pachinko machines 10 is simultaneously turned on, the reference times of the plurality of pachinko machines 10 basically match.

In step SB412, the reference time is grasped based on the date and time information stored in the RTC memory 357. Also, the current date and time information of the RTC 356 is read. Then, it is determined whether or not the time difference between the reference time and the time corresponding to the current date and time information read from the RTC 356 is an integral multiple of the predetermined time. When an affirmative determination is made in step SB412, time-corresponding effect setting processing is executed (step SB413). In the time-corresponding effect setting process, the display light emitting unit 53 and the speaker unit 54 are set to execute the time-corresponding effect, and the symbol display device 41 issues a command to execute the time-corresponding effect. 82. Note that the execution content of the time-corresponding effect may be different depending on the number of times the time-corresponding effect is executed when the reference time corresponding to the date and time information stored in the RTC memory 357 is used as a reference.

When a negative determination is made in step SB412 or the process of step SB413 is executed, other processes are executed (step SB414). In other processing, when the command to start the game use effect is received from the main CPU 63, the symbol display device 41, the display light emitting unit 53, and the speaker unit 54 are used to start the game use effect. When the settings are made and the situation for the game use is to be advanced, the settings for advancing the game use effect are made by the symbol display device 41, the display light emitting section 53 and the speaker section 54, and the game time is set. When it is a situation in which the effect for use is to be ended, the pattern display device 41, the display light emitting unit 53, and the speaker unit 54 are set to end the effect for game play. Further, in other processing, when a command to start the effect for the opening/closing execution mode is received from the main CPU 63, the effect for the opening/closing execution mode is provided by the symbol display device 41, the display light emitting unit 53, and the speaker unit 54. In order to proceed with the opening/closing execution mode effect by the symbol display device 41, the display light emitting unit 53, and the speaker unit 54, when the setting for starting is performed and the effect for the opening/closing execution mode is to be advanced. When the setting is performed and the effect for the opening/closing execution mode is to be ended, the symbol display device 41, the display light emitting unit 53, and the speaker unit 54 are set for ending the effect for the opening/closing execution mode.

Next, the operation corresponding to the content of the processing executed in the processing (step SB101 to step SB122) at the time of starting the supply of the operating power in the main CPU 63 will be described with reference to the explanatory diagram of FIG.

All of the first RAM clearing process (step SB117), the setting confirmation process (FIG. 166), and the setting value updating process (FIG. 167) in the process (step SB101 to step SB122) at the time of starting the supply of the operating power in the main CPU 63. If the process is not executed, the main CPU 63 sends a normal return command to the sound/light side CPU 353 when the process (step SB101 to step SB122) at the start of supply of the operating power ends. When the sound-light side CPU 353 receives the normal return command, the control relating to the notification is not executed for the normal return command. On the other hand, when the sound-light side CPU 353 receives the normal return command, it stores the current date and time information measured by the RTC 356 in the RTC memory 357. As a result, the information corresponding to the reference time referred to for specifying the execution trigger of the time-corresponding effect is newly stored in the RTC memory 357.

When the first RAM clear process (step SB117) is executed in the process (step SB101 to step SB122) at the start of supplying the operating power in the main CPU 63, the process at the start of supplying the operating power (step SB101 to step SB122) When the process ends, the main CPU 63 transmits a clear return command to the sound/light side CPU 353. When the sound-light side CPU 353 receives the return command at the time of clearing, it does not execute the control related to the notification. Further, the sound-light side CPU 353 does not store the current date and time information measured by the RTC 356 in the RTC memory 357 even if the clear-time return command is received. Since the backup power is supplied to the RTC memory 357, if the RTC memory 357 does not store new date and time information, the RTC memory is turned off before the pachinko machine 10 is powered off. The date and time information stored in 357 is stored and retained as it is.

When the setting value updating process (FIG. 167) is executed in the process (step SB101 to step SB122) at the time of starting the supply of the operating power in the main CPU 63, the process at the start of the supplying of the operating power (step SB101 to step SB122). When the process ends, the main CPU 63 transmits a return command at the time of updating to the sound-light CPU 353. When receiving the update return command, the sound-light side CPU 353 ends the notification corresponding to the execution of the set value update processing (FIG. 167). Further, the sound-light side CPU 353 does not store the current date and time information measured by the RTC 356 in the RTC memory 357 even when the return command at the time of updating is received. Since the backup power is supplied to the RTC memory 357, if the RTC memory 357 does not store new date and time information, the RTC memory is turned off before the pachinko machine 10 is powered off. The date and time information stored in 357 is stored and retained as it is.

When the setting confirmation process (FIG. 166) is executed in the process (step SB101 to step SB122) at the time of starting the supply of the operating power in the main CPU 63, the process at the start of the supply of the operating power (step SB101 to step SB122). When the process ends, the main CPU 63 transmits a return command for confirmation to the sound/light side CPU 353. When the sound-light side CPU 353 receives the return command for confirmation, it terminates the notification corresponding to the execution of the setting confirmation process (FIG. 166). Even if the sound-light side CPU 353 receives the return command at the time of confirmation, it does not store the current date and time information measured by the RTC 356 in the RTC memory 357. Since the backup power is supplied to the RTC memory 357, if the RTC memory 357 does not store new date and time information, the RTC memory is turned off before the pachinko machine 10 is powered off. The date and time information stored in 357 is stored and retained as it is.

According to this embodiment described in detail above, the following excellent effects are exhibited.

When the set value update process (FIG. 167) is started, the set value is changed from the set value corresponding to a predetermined start. As a result, regardless of the setting value to be used before the setting value updating process (FIG. 167) is started, in the setting value updating process (FIG. 167), an operation for changing the setting value from a certain start corresponding setting value is performed. It becomes possible to do. Therefore, the work content of the operation of changing the set value becomes easy for the operator to understand.

Specifically, the setting value corresponding to the start is “setting 1” having the lowest advantage. Therefore, when the setting value update process (FIG. 167) is started, the setting value is changed from “setting 1” having the lowest advantage. As a result, even if the manager of the game hall unintentionally terminates the set value update processing (FIG. 167) immediately after the start of the set value update processing (FIG. 167), the setting value with the lowest advantage is obtained. Therefore, even if the game is started in such a situation, it is possible to prevent an unintended disadvantage from occurring in the game hall.

The work area 221 for specific control is provided with a setting reference area 341 and a setting update area 342, and information corresponding to the setting value to be used is stored in the setting reference area 341, and the setting value update processing is performed. The information corresponding to the setting value being changed in the situation where (FIG. 167) is being executed is stored in the setting update area 342. As a result, while the setting reference area 341 stores and holds the information of the setting value set before the setting value updating process (FIG. 167) is started, the setting value update process (FIG. 167) sets the target of updating. It is possible to change the set value.

When the main CPU 63 starts the supply of the operating power, when the first RAM clearing process (step SB117) is executed, the clear return command is transmitted, and the set value updating process (FIG. 167) is executed. A return command at the time of update is transmitted, and when the process for setting confirmation (FIG. 166) is executed, a return command at the time of confirmation is transmitted, these first RAM clear process (step SB117), set value update process (FIG. 167), and If none of the setting confirmation processing (FIG. 166) is executed, the normal return command is transmitted. As a result, it is possible to control not only the main CPU 63 but also the sound/light side CPU 353 to perform control corresponding to the type of the start situation when the supply of the operating power is started.

The sound-light side CPU 353 makes a positive determination in step SB405 of the effect control process (FIG. 173) regardless of which of the normal return command, the clear return command, the update return command and the confirmation return command is received. Then, the state becomes such that the processes of steps SB412 to SB414 are executed. On the other hand, when the normal return command is received, the write processing to the RTC memory 357 (step SB407) is executed, and when the update return command is received, the update notification end processing (step SB409) is executed. If the return command at the time of confirmation is received, the confirmation notification end process (step SB411) is executed, and if the return command at the time of clear is received, the dedicated process is not executed. As a result, the control corresponding to each return command is performed while the process corresponding to the progress of the game is started in the sound-light side CPU 353 upon reception of any one of the return commands. It can be executed by the side CPU 353.

The main CPU 63 terminates the process (step SB101 to step SB122) at the time of starting the supply of the operating power after transmitting any return command and starts the process (step S8907 to step S8920) for controlling the progress of the game. Then, the sound-light side CPU 353 performs execution control of the effect corresponding to the progress content of the game when any of the return commands is received. As a result, after the processing for controlling the progress of the game is executed by the main CPU 63, the sound-light side CPU 353 controls the execution of the effect corresponding to the progress of the game. Is possible. In this case, the sound-light side CPU 353 executes a process corresponding to each return command. With this, by using a plurality of return commands that cause the sound-light side CPU 353 to differ in the content of execution of processing at the start of supply of operating power, the sound-light side CPU 353 triggers the start of execution control of the effect corresponding to the progress of the game. Can be made to recognize.

Since the time-corresponding effect is executed when the execution timing of the time-corresponding effect is reached based on the date and time information stored in the RTC memory 357, the time-corresponding effect is executed at the timing when the predetermined time comes. It becomes possible to In this case, when the first RAM clearing process (step SB117), the set value updating process (FIG. 167), or the setting confirmation process (FIG. 166) is executed when the supply of the operating power to the main CPU 63 is started. No new storage of date and time information in the RTC memory 357 occurs, but the first RAM clearing process (step SB117), the set value updating process (FIG. 167), and the setting confirming process (FIG. 166) are all executed. If not, the current date and time information measured by the RTC 356 is stored in the RTC memory 357. This allows the RTC memory 357 to newly store date and time information according to the content of processing executed by the main CPU 63 when the supply of operating power to the main CPU 63 is started, and the RTC memory. It is possible to cause a situation in which the date and time information is not newly stored in the memory 357.

When the "RAM clear operation" is performed when the supply of the operating power to the main CPU 63 is started, the first RAM clear process (step SB117) is executed, and the "setting change operation" is performed. The setting value update processing (FIG. 167) is executed, and when the “setting confirmation operation” is performed, the setting confirmation processing (FIG. 166) is executed. On the other hand, when the supply of operating power to the main CPU 63 is started in the “no operation” situation, the first RAM clear process (step SB117), the set value update process (FIG. 167) and the setting confirmation process (FIG. 166). ) Is not executed. In this case, the first RAM clear process (step SB117), the set value update process (FIG. 167) or the setting confirmation process (FIG. 166) is executed when the supply of the operating power to the main CPU 63 is started as described above. If so, no new storage of date and time information in the RTC memory 357 occurs, but any of the first RAM clearing process (step SB117), the setting value updating process (FIG. 167), and the setting confirmation process (FIG. 166). The current date and time information measured by the RTC 356 when the memory is not executed is stored in the RTC memory 357. Thus, when the power of the pachinko machine 10 is turned on, whether the date and time information is newly stored in the RTC memory 357 or the date and time information is not newly stored in the RTC memory 357. It becomes possible for the manager of the game hall to select.

When the supply of the operating power to the main CPU 63 is started, the residual processing (step SB125 to step SB125) is performed after the processing at the start of the supply of the operating power (step SB101 to step SB122) is completed in the main CPU 63. Before the SB128) is started, the initial check period is started. Accordingly, since it is not necessary to control the initial check period in the situation where the processing at the start of supplying the operating power is executed, the processing load in the situation where the processing at the start of supplying the operating power is executed is reduced. It becomes possible.

The setting confirmation process (FIG. 166) and the set value update process (FIG. 167) are executed as the process at the start of supplying the operating power (steps SB101 to SB122), while the initial check period supplies the operating power. It is started after the processing at the start is completed. Accordingly, even if the check display is performed on the first to fourth notification display devices 201 to 204 during the initial check period, the set values are displayed using the first to fourth notification display devices 201 to 204. It becomes possible not to affect.

When the supply of operating power to the main CPU 63 is started, either the setting confirmation process (FIG. 166) or the setting value update process (FIG. 167) is executed, and the setting confirmation process (FIG. 166) and the set value updating process (FIG. 167) are not executed, the check display is performed on the first to fourth notification display devices 201 to 204. This makes it possible to confirm whether or not the first to fourth notification display devices 201 to 204 are normal regardless of the situation when the supply of the operating power to the main CPU 63 is started.

In the main process (FIG. 165) of the main CPU 63, when either the setting confirmation process (FIG. 166) or the setting value update process (FIG. 167) is executed, and the setting confirmation process (FIG. 166) and the setting process are performed. This is a process that is commonly executed even when neither of the value update processes (FIG. 167) is executed, and either of the setting confirmation process (FIG. 166) and the set value update process (FIG. 167). When the execution is performed, the first to fourth notification display devices 201 to 204 are checked as the processing whose execution order is later than those of the setting confirmation processing (FIG. 166) and the setting value update processing (FIG. 167). The process to start the message display is set. In this way, the processing for starting the check display on the first to fourth notification display devices 201 to 204 is set as the common processing, so that the processing configuration is simplified and excellent as already described. It is possible to achieve the effect.

Even when the check display is being executed on the first to fourth notification display devices 201 to 204, the main CPU 63 can start the process for advancing the game. Thereby, even if the check display is performed on the first to fourth notification display devices 201 to 204 after the setting confirmation process (FIG. 166) or the set value update process (FIG. 167) is executed, the game is played. It is possible to prevent the start timing of the processing for advancing from being delayed.

In the process (step SB101 to step SB122) at the time of starting the supply of the operating power, which is executed when the supply of the operating power is started in the main CPU 63, it is determined whether or not the set value of the use target is within the normal range. Processing for monitoring is executed. Then, when the set value of the use target is abnormal, the processing for advancing the game is in a restricted state in which the processing is not started. As a result, it is possible to prevent the processing for advancing the game from being started even though the setting value of the use target is abnormal.

The process for monitoring whether or not the set value of the use target is within the normal range is the first timer interrupt process (FIG. 133) even after the process at the start of supplying the operating power (step SB101 to step SB122) is completed. ) Is executed in step S8919. As a result, even if the set value to be used becomes abnormal in the course of the game, it is possible to deal with it.

Whether or not the setting value to be used is within the normal range in the process at the start of the supply of the operating power (step SB101 to step SB122) executed when the supply of the operating power is started in the main CPU 63 Not only the monitoring but also the monitoring of whether the power failure flag in the work area 221 for specific control is set to "1" is executed, and the work area 221 for specific control and the stack area 222 for specific control are checked. Monitoring of whether or not the thumb is normal is performed. Then, when "1" is not set in the power failure flag or when the checksum is abnormal, there is a restriction state in which the process for advancing the game is not started. As a result, it is possible to prevent the processing for advancing the game from being started even though the information abnormality has occurred in the main RAM 65.

The regulation state is resumed when the supply of the operating power is resumed even if the supply of the operating power is stopped. As a result, it is possible to prevent the state in which the execution of the process for advancing the game is restricted due to the occurrence of the information abnormality with respect to the main side RAM 65, from being canceled only by stopping the supply of the operating power. Become.

The restricted state is canceled by executing the set value updating process (FIG. 167). As a result, when the state where the progress of the game is restricted due to the occurrence of the information abnormality with respect to the main side RAM 65 is released, it becomes possible to newly set the set value to be used.

Even in the regulated state, power failure monitoring and various counter update processing are executed. As a result, it becomes possible to ensure the execution of the necessary processing even when the progress of the game is restricted as described above. In particular, by executing the power outage monitoring, it is possible to appropriately cope with the power outage even if the progress of the game is restricted.

When the regulated state is reached, it is informed that the setting value of the usage target should be changed. This makes it possible to prompt the manager of the game hall to eliminate the abnormal information in the main RAM 65.

When an information abnormality has occurred with respect to the main RAM 65, an abnormality signal is externally output to the management computer of the game hall. This makes it possible to prompt the manager of the game hall to eliminate the abnormal information in the main RAM 65.

An abnormality signal is externally output to the management computer of the game hall when an abnormality different from the information abnormality of the main RAM 65 occurs. As a result, it is possible to combine the configuration for performing external output.

Even if the supply of the operating power to the main CPU 63 is stopped in the restricted state where the progress of the game is restricted due to the occurrence of the information abnormality regarding the main RAM 65, it is still restricted when the supply of the operating power is restarted. When the state is not released, the external output of the abnormal signal is performed again. As a result, in the regulated state, the abnormal signal is externally output every time the supply of operating power is restarted. Therefore, it becomes easy for the manager of the game hall to recognize that the information abnormality has occurred in the main RAM 65.

The first timer interrupt process (FIG. 133) in a situation where the setting confirmation process (FIG. 166) and the set value update process (FIG. 167) are not executed in the process (step SB101 to step SB122) at the start of supply of operating power. In the situation where the execution of the second timer interrupt process (FIG. 134) is prohibited and the setting confirmation process (FIG. 166) or the set value update process (FIG. 167) is being executed, the first timer interrupt process (FIG. 133) and Execution of the second timer interrupt process (FIG. 134) is permitted. If the setting confirmation process (FIG. 166) and the set value update process (FIG. 167) are not executed, the timer interrupt process is not interrupted and activated during the process (step SB101 to step SB122) at the start of supplying the operating power. By doing so, it becomes possible to complete the processing (step SB101 to step SB122) at the start of supplying the operating power at an early stage.

On the other hand, when the setting confirmation process (FIG. 166) and the setting value update process (FIG. 167) are executed, the process according to the operation of the manager of the game hall is executed. Becomes longer. In this case, even if the setting confirmation process (FIG. 166) and the set value update process (FIG. 167) are being executed, assuming that the interrupt of the timer interrupt process remains disabled, the execution of the timer interrupt process starts. The timing is extremely late. On the other hand, when the setting confirmation process (FIG. 166) or the set value update process (FIG. 167) is executed, the interrupt of the timer interrupt process is permitted. This makes it possible to prevent the execution start timing of the timer interrupt processing from being extremely delayed. Further, in a situation where the setting confirmation process (FIG. 166) and the setting value update process (FIG. 167) are being executed, the process for display control of the first to fourth notification display devices 201 to 204 is executed. When the second timer interrupt process (FIG. 134) is executed by interruption, the second timer interrupt process (FIG. 134) is used to display the set values on the first to fourth notification display devices 201 to 204. It is possible to do it.

Further, in the situation where the setting confirmation process (FIG. 166) or the set value update process (FIG. 167) is being executed, “1” is set in the startup processing flag. Therefore, even if the first timer interrupt process (FIG. 133) is activated in the situation where the setting confirmation process (FIG. 166) or the set value update process (FIG. 167) is being executed, the first timer interrupt process (FIG. It is possible to prevent the processing for advancing the game from being executed while the processing for performing power failure monitoring, updating various counters, and fraudulent monitoring among various processing of 133) is executed.

When neither the first RAM clearing process (step SB117), the set value updating process (FIG. 167) nor the setting confirmation process (FIG. 166) is executed, new storage of date and time information in the RTC memory 357 occurs. However, when any of the first RAM clearing process (step SB117), the set value updating process (FIG. 167) and the setting confirming process (FIG. 166) is executed, the date and time information is newly stored in the RTC memory 357. It is not limited to the configuration that does not occur. For example, when neither the first RAM clear process (step SB117), the set value update process (FIG. 167) nor the setting confirmation process (FIG. 166) is executed, or the first RAM clear process (step SB117) is executed Alternatively, the RTC memory 357 may be newly stored with the date and time information. When neither the first RAM clear process (step SB117), the set value update process (FIG. 167) nor the setting confirmation process (FIG. 166) is executed, or the set value update process (FIG. 167) is executed Alternatively, the RTC memory 357 may be newly stored with the date and time information. When neither the first RAM clearing process (step SB117), the setting value updating process (FIG. 167) nor the setting confirmation process (FIG. 166) is executed, or the setting confirmation process (FIG. 166) is executed Alternatively, the RTC memory 357 may be newly stored with the date and time information.

When neither the first RAM clear process (step SB117), the set value update process (FIG. 167) nor the setting confirmation process (FIG. 166) is executed, or the set value update process (FIG. 167) is executed, Alternatively, the configuration may be such that new storage of date and time information in the RTC memory 357 occurs when the setting confirmation process (FIG. 166) is executed. When neither the first RAM clear process (step SB117), the set value update process (FIG. 167) nor the setting confirmation process (FIG. 166) is executed, or the first RAM clear process (step SB117) is executed, Alternatively, the configuration may be such that new storage of date and time information in the RTC memory 357 occurs when the setting confirmation process (FIG. 166) is executed. When neither the first RAM clear process (step SB117), the set value update process (FIG. 167) nor the setting confirmation process (FIG. 166) is executed, or the first RAM clear process (step SB117) is executed, Alternatively, the configuration may be such that new storage of date and time information in the RTC memory 357 occurs when the set value update processing (FIG. 167) is executed.

Further, when the first RAM clearing process (step SB117) is executed, new storage of date and time information occurs in the RTC memory 357, and in other cases, new date and time information is stored in the RTC memory 357. The storage may not occur. Further, when the set value update processing (FIG. 167) is executed, new storage of date and time information in the RTC memory 357 occurs, and in other cases, new date and time information is stored in the RTC memory 357. The storage may not occur. When the setting confirmation process (FIG. 166) is executed, new storage of date and time information occurs in the RTC memory 357, and in other cases, new date and time information is stored in the RTC memory 357. The storage may not occur. Further, when the first RAM clearing process (step SB117) or the set value updating process (FIG. 167) is executed, new storage of date and time information occurs in the RTC memory 357, and in other cases, it is used for the RTC. A configuration may be adopted in which new storage of date and time information in the memory 357 does not occur. When the first RAM clear process (step SB117) or the setting confirmation process (FIG. 166) is executed, new storage of date and time information occurs in the RTC memory 357, and in other cases, the RTC memory 357. The date and time information may not be newly stored in the configuration. Further, when the setting value update process (FIG. 167) or the setting confirmation process (FIG. 166) is executed, new storage of the date and time information occurs in the RTC memory 357, and in other cases, the RTC memory is used. A configuration may be adopted in which new storage of date and time information in the memory 357 does not occur.

In addition, when the set value update process (FIG. 167) is executed, the entire work area 221 for specific control including the setting reference area 341 and the setting update area 342 in the initial setting at the start (step SB303). The area may be cleared to "0" and initialized. In this case, the second RAM clearing process (step SB313) may not be executed in the set value updating process (FIG. 167).

Further, when the setting value update process (FIG. 167) is started, the setting value may be changed from a predetermined setting value other than “setting 1”. For example, the configuration may be changed from "setting 2", the setting may be changed from "setting 3", or the setting may be changed from "setting 4". The configuration may be changed, the setting value may be changed from “setting 5”, or the setting value may be changed from “setting 6”.

When the setting value update processing (FIG. 167) is started, the setting value information stored in the setting reference area 341 is overwritten in the setting update area 342 as in the 45th embodiment. As a result, the setting value may be changed from the setting value that has been set as the usage target until then.

Further, the process for transmitting various return commands in the main process (FIG. 165) may be set as a process before the residual process (step SB125 to step SB128) is started. In this case, when any one of the first RAM clearing process (step SB117), the set value updating process (FIG. 167) and the setting confirmation process (FIG. 166) is executed, a flag corresponding to the process is set, and In the processing for transmitting various return commands, the return command corresponding to the state of the flag may be transmitted to the sound-light side CPU 353.

Further, in addition to or instead of the configuration in which the time-corresponding effect is executed every time a predetermined time elapses with reference to the date/time information stored in the RTC memory 357, the date/time information stored in the RTC memory 357 is used as a reference. As a configuration, it may be configured to monitor whether or not a predetermined abnormality occurs every time a predetermined time elapses, and each time a predetermined time elapses with reference to the date and time information stored in the RTC memory 357. The base value may be notified. In this case, the RTC 356 and the RTC memory 357 may be provided on the main control board 61, and the main CPU 63 may monitor the abnormality or notify the base value. A plurality of pachinko machines 10 installed in the game hall perform abnormality monitoring at the same time, and the result is notified by, for example, the symbol display device 41 or the like, so that whether or not a predetermined abnormality has occurred is regularly performed. It is possible to perform various types of monitoring collectively for a plurality of pachinko machines 10. In addition, the plurality of pachinko machines 10 set in the game hall simultaneously notify the base value on the symbol display device 41 or the like, so that the base values are regularly monitored for the plurality of pachinko machines 10. It becomes possible to do it. The above-mentioned various notifications are not limited to the configuration performed by the pachinko machine 10 itself, and may be configured to be performed by external output to the management computer in the game hall.

Further, in the main process (FIG. 165), it is determined that the power failure flag is not set to "1", the checksum is determined to be abnormal, or the setting value of the setting reference area 341 is abnormal. When the determination is made, the setting value update process (FIG. 165) may be forcibly executed regardless of whether or not the “setting change operation” is performed. This makes it possible to immediately change the set value when an information abnormality has occurred in the main RAM 65.

<50th Embodiment>
In this embodiment, the processing configuration of the effect control processing executed by the sound-light side CPU 353 is different from that in the forty-ninth embodiment. Hereinafter, a configuration different from that of the 49th embodiment will be described. Note that the description of the same configuration as the 49th embodiment is basically omitted.

FIG. 175 is a flowchart showing the effect control process in the present embodiment, which is executed by the sound-light side CPU 353.

In Step SB501 to Step SB505, the same processing as Step SB401 to Step SB405 of the effect control processing (FIG. 173) in the forty-ninth embodiment is executed. When any of the normal return command, the clear return command, the check return command, and the update return command are received from the main CPU 63 (step SB505: YES), the return command received this time is other than the normal return command. It is determined whether the command is a return command (step SB506).

When the return command received this time is one of the return command for clear, the return command for confirmation, and the return command for update (step SB506: YES), the effect control process in the forty-ninth embodiment (FIG. 173). Similar to step SB407 in step S407, the current date and time information of the RTC 356 is read and the read date and time information is stored in the RTC memory 357 (step SB407). As a result, the RTC memory 357 stores the date and time information serving as a reference when specifying the timing for executing the time-based effect.

In steps SB508 to SB514, the same processes as steps SB408 to SB414 of the effect control process (FIG. 173) in the forty-ninth embodiment are executed.

FIG. 176 is an explanatory diagram for describing an action corresponding to the content of the process executed in the process (step SB101 to step SB122) at the time of starting the supply of the operating power in the main CPU 63.

Similar to the forty-ninth embodiment, the first CPU clear process (step SB117), the setting confirmation process (FIG. 166), and the process at the start of supply of operating power in the main CPU 63 (steps SB101 to SB122) are performed. When none of the set value update processing (FIG. 167) is executed, the main CPU 63 sends a normal return command to the sound/light side CPU 353, and when the first RAM clear processing (step SB117) is executed, The main CPU 63 sends a return command at the time of clearing to the sound/light side CPU 353, and when the set value update processing (FIG. 167) is executed, the main side CPU 63 sends a return command at the time of updating to the sound/light side CPU 353. When the setting confirmation process (FIG. 166) is executed, the main CPU 63 sends a confirmation return command to the sound/light side CPU 353.

Similarly to the forty-ninth embodiment, the sound-light side CPU 353 terminates the notification corresponding to the execution of the set value update processing (FIG. 167) when the update return command is received, and at the time of confirmation. When the return command is received, the notification corresponding to the execution of the setting confirmation process (FIG. 166) is ended. Further, even when the sound-light side CPU 353 receives the normal return command and the return command at the time of clearing, similarly to the forty-ninth embodiment, the notification control is not executed for that.

The sound/light-side CPU 353 stores the current date and time information measured by the RTC 356 in the RTC memory 357 when receiving any of the clear return command, the update return command, and the confirmation return command. As a result, the information corresponding to the reference time referred to for specifying the execution trigger of the time-corresponding effect is newly stored in the RTC memory 357. On the other hand, the sound-light side CPU 353 does not store the current date and time information measured by the RTC 356 in the RTC memory 357 even if the normal return command is received. Since the backup power is supplied to the RTC memory 357, if new storage of date and time information in the RTC memory 357 does not occur, the RTC memory 357 is used before the pachinko machine 10 is powered off. The date and time information stored in the memory 357 is stored and retained as it is.

According to the above configuration, any one of the first RAM clearing process (step SB117), the set value updating process (FIG. 167), and the setting confirmation process (FIG. 166) in the process (step SB101 to step SB122) at the start of supplying the operating power. Is executed, the date and time information stored in the RTC memory 357 is rewritten to the current date and time information measured by the RTC 356, while the process at the start of supplying the operating power (step SB101 to step SB101). If neither the first RAM clearing process (step SB117), the set value updating process (FIG. 167) nor the setting confirmation process (FIG. 166) is executed in step SB122), it is stored in the RTC memory 357. The date and time information cannot be rewritten. As a result, even if the power of the pachinko machine 10 is once turned off for maintenance and operation check of the pachinko machine 10 during the operation of the game hall, in the situation of "no operation" at the time of restarting the supply of operation power after that. By turning on the power of the pachinko machine 10, it becomes possible to prevent the date and time information stored in the RTC memory 357 from being rewritten. Therefore, when the power of the pachinko machine 10 is once turned off during the operation of the game hall and the supply of operating power is restarted, the reference time of the time-corresponding effect is set to be the same as that of the surrounding pachinko machines 10 in the game hall. However, it becomes possible to enhance the operability for restarting the supply of the operating power to the pachinko machine 10.

Further, since the date and time information stored in the RTC memory 357 cannot be rewritten by performing the power-on operation of the pachinko machine 10 in the “no operation” state, the date and time information stored in the RTC memory 357. When the power of the pachinko machine 10 is turned on so that the contents are not rewritten, the first RAM clear process (step SB117), the set value update process (FIG. 167), and the setting confirmation process (FIG. 166) are not performed. It is possible to prevent the processing from being executed.

<51st Embodiment>
In this embodiment, the processing configuration of the main processing executed by the main CPU 63 is different from that in the 49th embodiment. Hereinafter, a configuration different from that of the 49th embodiment will be described. Note that the description of the same configuration as the 49th embodiment is basically omitted.

FIG. 177 is a flowchart showing the main processing executed in the main CPU 63 in this embodiment. The processes of steps SB601 to SB630 in the main process are executed by using the program for specific control and the data for specific control in the main CPU 63.

Steps SB601 to SB622 execute the same processes as steps SB101 to SB122 of the main process (FIG. 165) in the forty-ninth embodiment.

When the process of step SB612 is executed, the process of step SB613 is executed, the process of step SB615 is executed, the process of step SB618 is executed, or the process of step SB622 is executed, Information corresponding to the initial check period (specifically, 5 seconds) is set in the checking counter provided in the work area 221 (step SB623). The value set in the checking counter is decremented by 1 each time the second timer interrupt process (FIG. 134) is activated, as in the 35th embodiment. When the value of 1 or more is set in the checking counter, the check display is continued on the first to fourth notification display devices 201 to 204 as in the 35th embodiment.

According to the above configuration, when the supply of the operating power to the main CPU 63 is started, the residual processing is performed after the processing at the start of the supply of the operating power (steps SB601 to SB622) is completed in the main CPU 63. The initial check period is started before (steps SB627 to SB630) are started. Accordingly, since it is not necessary to control the initial check period in the situation where the processing at the start of supplying the operating power is executed, the processing load in the situation where the processing at the start of supplying the operating power is executed is reduced. It becomes possible.

Further, while the setting confirmation process (FIG. 166) and the setting value update process (FIG. 167) are executed as the process at the start of the supply of the operating power (steps SB601 to SB622), the initial check period is the operating power. The process is started after the process at the start of the supply has been completed. Accordingly, even if the check display is performed on the first to fourth notification display devices 201 to 204 during the initial check period, the set values are displayed using the first to fourth notification display devices 201 to 204. It becomes possible not to affect.

After that, interrupt permission is set (step SB624). As a result, the first timer interrupt process (FIG. 133) is interrupted and activated in the first interrupt cycle, and the second timer interrupt process (FIG. 134) is interrupted and activated in the second interrupt period. When the second timer interrupt process (FIG. 134) is started by interruption, the first to fourth notification display devices are displayed so that the check display is performed in the situation where the check counter is set to a value of 1 or more. Display control of 201 to 204 is performed.

Then, it is determined whether the value of the checking counter in the specific control work area 221 is "0" (step SB625). Then, the process waits at step SB625 until the value of the checking counter becomes "0". In this case, since the state in which the start-up processing flag in the specific control work area 221 is set to "1" is maintained, even if the first timer interrupt processing (FIG. 133) is started by interruption. Of the various processes of the first timer interrupt process (FIG. 133), the process for performing power failure monitoring, updating various counters, and fraud monitoring is executed, while the process for advancing the game is not executed. The first timer interrupt process (FIG. 133) is completed. Therefore, until the initial check period set in step SB623 elapses, a check display is displayed on the first to fourth notification display devices 201 to 204 in a situation where execution of a process for advancing a game is blocked. Is continued.

After that, the start-up processing flag in the work area 221 for specific control is cleared to "0" (step SB626). When the first timer interrupt process (FIG. 133) is started by clearing the start-up processing flag “0”, a negative determination is made in step S8906, and thus not only the processes of steps S8901 to S8905 The processing of steps S8907 to S8920 will be executed, and the state where the processing for advancing the game is not executed is released. In step SB626, the power failure flag in the specific control work area 221 is also cleared to "0".

After that, the process proceeds to the residual processing of steps SB627 to SB630. In other words, the main CPU 63 is configured to periodically execute the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134), but between the one timer interrupt process and the next timer interrupt process. There will be some residual time. This remaining time will vary depending on the processing completion time of each timer interrupt processing, but the remaining processing of steps SB627 to SB630 is repeatedly executed by utilizing this irregular time. In this respect, it can be said that the residual process of steps SB627 to SB630 is an irregular process that is irregularly executed. In steps SB627 to SB630, the same processes as steps S113 to S116 of the main process (FIG. 9) in the first embodiment are executed.

According to the above configuration, the check display is performed on the first to fourth notification display devices 201 to 204 in the situation where the execution of the process for advancing the game is blocked. As a result, it is possible to check whether or not the first to fourth notification display devices 201 to 204 are normal in a situation where a game is not played.

<Fifty-second Embodiment>
In this embodiment, the processing configuration of the main processing executed by the main CPU 63 is different from that in the 49th embodiment. Hereinafter, a configuration different from that of the 49th embodiment will be described. Note that the description of the same configuration as the 49th embodiment is basically omitted.

FIG. 178 is a flowchart showing the main processing executed by the main CPU 63 in this embodiment. Note that the processing of steps SB701 to SB734 in the main processing is executed using the program for specific control and the data for specific control in the main CPU 63.

In the main process of this embodiment, unlike the forty-ninth embodiment, the power-on initialization process is not executed. Therefore, when the main processing is activated, the processing of step SB701 and thereafter is started without waiting for the predetermined time for waiting to elapse. Although the power-on initialization process is not executed, access to the main RAM 65 is permitted when the main process is started.

In the main process, first, the internal function register setting process is executed similarly to step SB102 of the main process (FIG. 165) in the forty-ninth embodiment (step SB701), and the main process in the forty-ninth embodiment (FIG. 165). As in step SB103 of step 1, "1" is set in the startup processing flag in the specific control work area 221 (step SB702). After that, the power failure flag is set to "1", the checksum is normal, the set value is normal, and the setting update display flag in the work area 221 for specific control is not set to "1". Under that condition (steps SB703 to SB705: YES, step SB706: NO), it is determined whether or not the reset button 68c has been pressed (step SB707).

When the reset button 68c has not been pressed (step SB707: NO), it is determined whether the game stop flag in the specific control work area 221 is set to "1" (step SB708). When "1" is not set in the game stop flag and the setting key insertion part 68a is turned on by using the setting key (step SB708: NO, step SB709: YES), or the game stop flag Is not set to "1" and the setting key insertion portion 68a is not turned on by using the setting key, and "1" is set to the setting confirmation display flag in the specific control work area 221. If so (step SB708 and step SB709: NO, step SB710: YES), the setting confirmation process is executed (step SB711). In the setting confirmation process, steps SB201 to SB202 and steps SB204 to SB207 are executed in the setting confirmation process (FIG. 166) in the forty-ninth embodiment.

That is, in the setting confirmation process of this embodiment, the confirmation start command is not transmitted to the sound-light side CPU 353. Therefore, in the present embodiment, even if the setting confirmation process is executed, the notification corresponding to the setting confirmation process is not executed by the symbol display device 41, the display light emitting unit 53, and the speaker unit 54. In the present embodiment, as described above, when the main process is started, the process after step SB701 is started without waiting for the predetermined time for weight to elapse, so that the design confirmation process is started at the timing. There is a possibility that the operation start and initial setting of the display device 41 have not been completed. On the other hand, as described above, by making the symbol display device 41 not perform the notification corresponding to the setting confirmation process, the display control of the symbol display device 41 is started in the situation where the initial setting is not completed. It is possible to prevent it. The notification corresponding to the setting confirmation process may be performed by the display light emitting unit 53 and the speaker unit 54 but not by the symbol display device 41.

After the setting confirmation process is executed, information corresponding to the initial check period (specifically, 5 seconds) is set in the checking counter provided in the specific control work area 221 (step SB712). The value set in the checking counter is decremented by 1 each time the second timer interrupt process (FIG. 134) is activated, as in the 35th embodiment. When the value of 1 or more is set in the checking counter, the check display is continued on the first to fourth notification display devices 201 to 204 as in the 35th embodiment. That is, when the setting confirmation process is executed in the process (step SB701 to step SB729) at the start of supplying the operating power, the first to fourth notification display devices 201 to 201 are executed after the setting confirmation process is completed. The check display is started at 204, and the check display is performed in a situation where the progress of the process is not waiting.

When the reset button 68c is not pressed and the game stop flag is not set to "1", and the setting key insertion portion 68a is not turned on by using the setting key, the work for specific control is performed. When "1" is not set in the setting confirmation display flag in the area 221 (step SB707 to step SB710: NO), the checking counter provided in the work area 221 for specific control is set to the initial check period (specifically, The information corresponding to 5 seconds) is set (step SB713). The value set in the checking counter is decremented by 1 each time the second timer interrupt process (FIG. 134) is activated, as in the 35th embodiment. When the value of 1 or more is set in the checking counter, the check display is continued on the first to fourth notification display devices 201 to 204 as in the 35th embodiment.

After that, interrupt permission is set (step SB714). As a result, the first timer interrupt process (FIG. 133) is interrupted and activated in the first interrupt cycle, and the second timer interrupt process (FIG. 134) is interrupted and activated in the second interrupt period. When the second timer interrupt process (FIG. 134) is started by interruption, the first to fourth notification display devices are displayed so that the check display is performed in the situation where the check counter is set to a value of 1 or more. Display control of 201 to 204 is performed.

Then, the weighting process is executed (step SB715). In the wait process, the process waits until the value of the checking counter in the specific control work area 221 becomes “0”. In this case, since the state in which the start-up processing flag in the specific control work area 221 is set to "1" is maintained, even if the first timer interrupt processing (FIG. 133) is started by interruption. Of the various processes of the first timer interrupt process (FIG. 133), the process for performing power failure monitoring, updating various counters, and fraud monitoring is executed, while the process for advancing the game is not executed. The first timer interrupt process (FIG. 133) is completed. Therefore, until the initial check period set in step SB713 elapses, the check display is displayed on the first to fourth notification display devices 201 to 204 in a situation in which execution of the process for advancing the game is blocked. Is continued. Also, the operation start and initial setting of the symbol display device 41 are completed during the waiting time in the weight process. That is, using the wait period for preventing the execution of the process for advancing the game until the operation start and initial setting of the symbol display device 41 are completed, the first to fourth notification display devices 201 to 204 are displayed. It is possible to make a check display. After the wait process (step SB715) is completed, the normal recovery command is transmitted to the sound-light side CPU 353 as in step SB113 of the main process (FIG. 165) in the forty-ninth embodiment (step SB716).

When the reset button 68c is pressed and the setting key insertion unit 68a is turned on by using the setting key (steps SB707 and SB717: YES), the set value updating process is executed (step SB718). Further, even when the setting update display flag in the specific control work area 221 is set to "1" regardless of whether or not the above "setting change operation" is performed (step SB706: YES). ), the set value update process is executed (step SB717). In the set value updating process, the processes of step SB301 to step SB304 and step SB306 to step SB314 are executed in the set value updating process (FIG. 167) in the forty-ninth embodiment.

That is, the update start command is not transmitted to the sound-light side CPU 353 in the setting value update processing of the present embodiment. Therefore, in the present embodiment, even if the setting value updating process is executed, the notification corresponding to the setting value updating process is not executed by the symbol display device 41, the display light emitting unit 53, and the speaker unit 54. In the present embodiment, as described above, when the main process is activated, the design value update process is started at the timing when the setting value update process is started in order to start the processes of step SB701 and thereafter without waiting for the predetermined time for waiting to elapse. There is a possibility that the operation start and initial setting of the display device 41 have not been completed. On the other hand, as described above, by making the symbol display device 41 not perform the notification corresponding to the setting value update processing, the display control of the symbol display device 41 is started in the situation where the initial setting is not completed. It is possible to prevent it. The notification corresponding to the set value updating process may be performed by the display light emitting unit 53 and the speaker unit 54, but not by the symbol display device 41.

After executing the setting value update process, information corresponding to the initial check period (specifically, 5 seconds) is set in the checking counter provided in the work area 221 for specific control (step SB719). The value set in the checking counter is decremented by 1 each time the second timer interrupt process (FIG. 134) is activated, as in the 35th embodiment. When the value of 1 or more is set in the checking counter, the check display is continued on the first to fourth notification display devices 201 to 204 as in the 35th embodiment. That is, when the set value update process is executed in the process (step SB701 to step SB729) at the start of supplying the operating power, the first to fourth notification display devices 201 to 201 are set after the set value update process is completed. The check display is started at 204, and the check display is performed in a situation where the progress of the process is not waiting.

When the reset button 68c is pressed and the setting key insertion part 68a is not turned on (step SB707: YES, step SB717: NO), the game stop flag in the specific control work area 221 is set to "1". On the condition that is not set (step SB720: NO), the first RAM clearing process is executed (step SB721). The processing contents of the first RAM clearing process are the same as the first RAM clearing process (step SB117) of the main process (FIG. 165) in the forty-ninth embodiment.

Then, information corresponding to the initial check period (specifically, 5 seconds) is set in the checking counter provided in the specific control work area 221 (step SB722). The value set in the checking counter is decremented by 1 each time the second timer interrupt process (FIG. 134) is activated, as in the 35th embodiment. When the value of 1 or more is set in the checking counter, the check display is continued on the first to fourth notification display devices 201 to 204 as in the 35th embodiment.

After that, the interrupt permission is set (step SB723). As a result, the first timer interrupt process (FIG. 133) is interrupted and activated in the first interrupt cycle, and the second timer interrupt process (FIG. 134) is interrupted and activated in the second interrupt period. When the second timer interrupt process (FIG. 134) is started by interruption, the first to fourth notification display devices are displayed so that the check display is performed in the situation where the check counter is set to a value of 1 or more. Display control of 201 to 204 is performed.

After that, the processing for weight is executed (step SB724). In the wait process, the process waits until the value of the checking counter in the specific control work area 221 becomes “0”. In this case, since the state in which the start-up processing flag in the specific control work area 221 is set to "1" is maintained, even if the first timer interrupt processing (FIG. 133) is started by interruption. Of the various processes of the first timer interrupt process (FIG. 133), the process for performing power failure monitoring, updating various counters, and fraud monitoring is executed, while the process for advancing the game is not executed. The first timer interrupt process (FIG. 133) is completed. Therefore, until the initial check period set in step SB722 elapses, the display for checking is displayed on the first to fourth notification display devices 201 to 204 in a situation where the execution of the process for advancing the game is blocked. Is continued. Also, the operation start and initial setting of the symbol display device 41 are completed during the waiting time in the weight process. That is, using the wait period for preventing the execution of the process for advancing the game until the operation start and initial setting of the symbol display device 41 are completed, the first to fourth notification display devices 201 to 204 are displayed. It is possible to make a check display. After the wait process (step SB724) is completed, a clear return command is transmitted to the sound-light side CPU 353 (step SB725), as in step SB118 of the main process (FIG. 165) in the forty-ninth embodiment.

If a negative determination is made in any of steps SB703 to SB705, after setting the game stop flag in the work area 221 for specific control to "1" (step SB726), whether the reset button 68c is pressed or not. It is determined (step SB727). When the reset button 68c is pressed and the setting key insertion part 68a is turned on by using the setting key (step SB717 and step SB727: YES), the set value updating process is performed in step SB718. Along with the execution, the setting process of the checking counter is executed in step SB719. The contents of these processes are as already described.

If the reset button 68c has not been pressed (step SB727: NO), it is determined that the game stop flag is set to "1" in step SB720, or the game stop flag is set to "1" in step SB708. If it is determined that is set, the processing of steps SB728 and SB729 is executed. The processing contents of these steps SB728 and SB729 are the same as those of steps SB121 and SB122 of the main processing (FIG. 165) in the forty-ninth embodiment.

When the process of step SB712 is executed, the process of step SB716 is executed, the process of step SB719 is executed, the process of step SB725 is executed, or the process of step SB729 is executed, The start-up processing flag in the work area 221 is cleared to "0" (step SB730). When the first timer interrupt process (FIG. 133) is started by clearing the start-up processing flag “0”, a negative determination is made in step S8906, and thus not only the processes of steps S8901 to S8905 The processing of steps S8907 to S8920 will be executed, and the state where the processing for advancing the game is not executed is released. In step SB730, the power failure flag in the specific control work area 221 is also cleared to "0".

After that, the process proceeds to the residual processing of steps SB731 to SB734. In other words, the main CPU 63 is configured to periodically execute the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134), but between the one timer interrupt process and the next timer interrupt process. There will be some residual time. This remaining time will vary depending on the processing completion time of each timer interrupt processing, but the remaining processing of steps SB731 to SB734 is repeatedly executed by utilizing the irregular time. In this respect, it can be said that the residual process of steps SB731 to SB734 is an irregular process that is irregularly executed. In steps SB731 to SB734, the same processing as steps S113 to S116 of the main processing (FIG. 9) in the first embodiment is executed.

According to the above configuration, when the setting confirmation process (step SB711) and the set value update process (step SB718) are not executed in the process (step SB701 to step SB729) at the time of starting the supply of the operating power, the weight process is executed. The check display is continued on the first to fourth notification display devices 201 to 204 while waiting for the process to proceed. Thereby, by using the wait period for preventing the execution of the process for advancing the game until the operation start and initial setting of the symbol display device 41 are completed, the first to fourth notification display devices 201 to 204 It is possible to display the check for. In addition, it is possible to secure an opportunity to confirm the check display on the first to fourth notification display devices 201 to 204 before the processing for advancing the game is started.

On the other hand, since the setting confirmation process (step SB711) or the setting value update process (step SB718) is not completed unless the setting key insertion part 68a is turned off by at least the manager of the game hall, these setting confirmation processes (step SB711) Alternatively, by the time the setting value update process (step SB718) is completed, the time that is longer than the time required to start the operation of the symbol display device 41 and complete the initial setting has elapsed. In this case, when the setting confirmation process (step SB711) or the set value update process (step SB718) is executed, the weight confirmation process is not executed, so that the setting confirmation process (step SB711) or the setting When the value update process (step SB718) is executed, it is possible to prevent the time required to start the process for advancing the game from becoming excessively long.

When the setting confirmation process (step SB711) or the setting value update process (step SB718) is executed, the first to the first after the setting confirmation process (step SB711) or the setting value update process (step SB718) are completed. 4 Check display is performed on the notification display devices 201 to 204. Accordingly, the check display is performed on the first to fourth notification display devices 201 to 204 while not affecting the display of the set value using the first to fourth notification display devices 201 to 204. It becomes possible.

<53rd Embodiment>
In this embodiment, the processing configuration of the main processing executed by the main CPU 63 is different from that in the 49th embodiment. Hereinafter, a configuration different from that of the 49th embodiment will be described. Note that the description of the same configuration as the 49th embodiment is basically omitted.

FIG. 179 is a flowchart showing the main processing executed in the main CPU 63 in this embodiment. Note that the processing of steps SB801 to SB826 in the main processing is executed using the program for specific control and the data for specific control in the main CPU 63.

First, power-on initialization processing is executed (step SB801). In the power-on initialization process, for example, a predetermined wait time (specifically, 1 second) elapses after the main process is started, and the process waits without proceeding to the next process. In the predetermined period for this weight, the operation start and initial setting of the symbol display device 41 are completed. Also, access to the main RAM 65 is permitted.

After that, an internal function register setting process is executed (step SB802). In the internal function register setting process, as in the 35th embodiment, the interrupt period of the first timer interrupt process (FIG. 133), which is a process that is activated by periodically interrupting the main process, is set to the first interrupt period. (Specifically, 4 ms), and the interrupt period of the second timer interrupt process (FIG. 134), which is a process that is periodically interrupted and activated with respect to the main process, is set from the first interrupt period. Is set to the second interrupt cycle (specifically, 2 milliseconds) which is a short cycle.

That is, in this embodiment, as in the 35th embodiment, the first timer interrupt processing (FIG. 133) and the second timer interrupt processing (FIG. 134) are performed so that the interrupt cycle becomes relatively short as the timer interrupt processing. And exist. Both the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134) are activated by interrupting the main process. The second timer interrupt process (FIG. 134) is activated by interrupting the first timer interrupt process (FIG. 133). On the other hand, the first timer interrupt process (FIG. 133) does not start by interrupting the second timer interrupt process (FIG. 134). In addition, when both the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134) are not executed, and when both the first interrupt cycle and the second interrupt cycle have passed, those cycles The second timer interrupt processing (FIG. 134) is started first regardless of the lapsed order of the above. In this respect, it can be said that the second timer interrupt process (FIG. 134) is a process that is activated prior to the first timer interrupt process (FIG. 133). However, the configuration is not limited to this, and the first timer interrupt process (FIG. 133) may be activated prior to the second timer interrupt process (FIG. 134).

In the internal function register setting process, the first interrupt period of the first timer interrupt process (FIG. 133) is set in a predetermined register of the main CPU 63, and the second interrupt period of the second timer interrupt process (FIG. 134) is set. It is set in a specific register of the side CPU 63. Further, in the internal function register setting process, in addition to the setting of the first and second interrupt cycles, the setting process of the numerical range of various counters such as the numerical range of the hit random number counter C1 is executed.

After that, "1" is set to the in-start-up processing flag provided in the work area 221 for specific control (step SB803). As in the 35th embodiment, the start-up processing flag is among the various processes set in the first timer interrupt process (FIG. 133) even if the first timer interrupt process (FIG. 133) is activated. While the power outage monitoring, the processing for updating various counters and the illegality monitoring are executed, the first timer interrupt processing (FIG. 133) should be terminated without executing the processing for advancing the game. This is a flag for specifying by the main CPU 63.

The start-up processing flag is set to "1" when the processing (step SB801 to step SB818, step SB823 to step SB826) at the start of supplying the operating power is started in the main processing (FIG. 165), and the operating power is set. Is cleared before the remaining process (step SB819 to step SB822) is started and the process at the start of the supply is finished. As in the 35th embodiment, in the first timer interrupt process (FIG. 133), when the start-up processing flag is set to "1", the processes of steps S8907 to S8920 are not executed. As a result, a setting confirmation process (step SB810) or a set value update process (FIG. 181), which will be described later, among the processes at the start of supply of operating power (steps SB801 to SB818, step SB823 to step SB826) are executed. It is possible to prevent the processing for advancing the game from being executed. On the other hand, as described above, in the first timer interrupt processing (FIG. 133), even if the start-up processing flag is set to "1", by executing the processing of steps S8901 to S8905, the operating power is reduced. Even if the setting confirmation process (step SB810) or the set value update process (FIG. 181) to be described later among the processes at the start of supply (step SB801 to step SB818, step SB823 to step SB826) is being executed. The power failure is monitored, the winning random number counter C1, the big hit type counter C2, the reach random number counter C3, and the random number initial value counter CINI are updated, and fraud is detected.

Particularly, even when the start-up processing in progress flag is set to "1", the power failure information storage processing (step S8901) is executed, so that the operation power supply start processing (steps SB801 to SB818) is started. , Step SB823 to Step SB826), even if a power failure occurs in a situation where the setting confirmation processing (Step SB810) or the set value update processing (FIG. 181) described later is being executed, the power failure processing is executed for it. It becomes possible. In the power failure process, as in the thirty-fifth embodiment, the power failure flag provided in the specific control work area 221 is set to "1", the checksum is calculated, and the calculated checksum is used for the specific control. Since the data is stored in the work area 221 of No. 1, it is possible to prevent the occurrence of an abnormality in the main RAM 65 when the supply of operating power is restarted. As a result, if a power outage occurs during the setting confirmation process (step SB810) or the set value update process (FIG. 181), the fact that a power outage has occurred during the setting related process is supplied to the next operating power. It is possible to specify at the start.

Incidentally, in the situation where the setting confirmation process (step SB810) or the set value update process (FIG. 181) is being executed, both the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134) are performed. Interrupts are not prohibited and can be interrupted at any timing. In this case, when the first timer interrupt process (FIG. 133) or the second timer interrupt process (FIG. 134) is activated in the setting confirmation process (step SB810) or the setting value update process (FIG. 181), The information on the return address of the main process (FIG. 179) for returning after the timer interrupt process that is the target of activation is saved in the stack area 222 for specific control, and the timer interrupt process is activated. Information of various registers of the main CPU 63 immediately before is saved in the stack area 222 for specific control. Then, when the timer interrupt process that is the activation target ends, the process returns to the process of the main process (FIG. 179) corresponding to the information of the return address saved in the stack area 222 for specific control, and The information saved in the stack area 222 for specific control is restored to various registers of the main CPU 63.

After setting the start-up processing flag to "1" in step SB803, it is determined whether the power failure flag provided in the work area 221 for specific control is set to "1" (step SB804). .. When the power failure information storage processing (step S8901) of the first timer interrupt processing (FIG. 133) executes the power failure processing, the power failure flag is set to "1". The power outage flag is a flag for the main CPU 63 to specify whether or not the power outage process was appropriately performed at the previous power off time.

When the power failure flag is set to "1" (step SB804: YES), it is determined whether the checksum is normal (step SB805). Specifically, first, checksums are calculated for the specific control work area 221 and the specific control stack area 222. The method of calculating the checksum is the same as in the 33rd embodiment. After that, the work area 221 for the specific control and the work area 221 for the specific control, which are calculated in the power failure process executed immediately before the supply of the operating power to the main CPU 63 is stopped and stored in the work area 221 for the specific control, are performed. The checksum for the stack area 222 is read, and the read checksum is compared with the checksum calculated as described above in the main processing this time. Then, it is determined whether the checksums match.

If the checksums match (step SB805: YES), is the setting value corresponding to the information stored in the setting reference area 341 (see FIG. 154) in the specific control work area 221 within the normal range? It is determined whether or not (step SB806). The setting reference area 341 is a storage area in which information for specifying the current setting value of the pachinko machine 10 by the main CPU 63 is stored as in the 45th embodiment. When the numerical information of “1” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 1”. When the numerical information of “2” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 2”. When the numerical information of “3” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 3”. When the numerical information of “4” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 4”. When the numerical information of “5” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 5”. When the numerical information of “6” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 6”. In step SB806, it is determined whether the setting value information stored in the setting reference area 341 is any of "1" to "6".

When a positive determination is made in all of steps SB804 to SB806, it is determined whether or not the reset button 68c is pressed (step SB807). That is, it is determined whether or not the power of the pachinko machine 10 is turned on while the reset button 68c is being pressed and the supply of operating power to the main CPU 63 is started. Here, in the present embodiment, as in the 35th embodiment, the main control device 60 is provided with the setting key insertion portion 68a and the reset button 68c, but is not provided with the update button 68b. Further, the main control device 60 is provided with not the first to third notification display devices 69a to 69c but the first to fourth notification display devices 201 to 204 as in the eleventh embodiment.

When the reset button 68c has not been pressed (step SB807: NO), it is determined whether or not "1" is set in the game stop flag or the setting update display flag provided in the work area 221 for specific control. (Step SB808).

The game stop flag is a flag that is set to "1" when "1" is not set in the power failure flag, when the checksums do not match, or when the set value is abnormal. When the game stop flag is set to "1", the processes of steps S8901 to S8905 are executed in the first timer interrupt process (FIG. 133), while the positive determination is made in step S8906 to steps S8907 to step. The process of S8920 is not executed. As a result, when the power failure flag is not set to “1” because the power failure process was not properly performed at the previous power shutdown, the work area 221 for the specific control and the stack area 222 for the specific control are If at least one of the checksums does not match due to the change in the information storage state since the last power-off, or if the set value is abnormal, power failure monitoring, updating of various counters and illegal operation While the processing for monitoring is executed, the processing for advancing the game is not executed.

The setting update display flag is a flag for the main CPU 63 to specify that the setting value update processing (FIG. 181) is being executed, as in the 35th embodiment, and the setting update display flag is "1". When is set, a display indicating that the setting value is being updated and a setting value being updated are displayed on the first to fourth notification display devices 201 to 204. The setting update display flag is a flag that is set to "1" when the setting value update process (FIG. 181) is started and is cleared to "0" when the setting value update process (FIG. 181) is ended. In the situation where the set value update process (FIG. 181) is not executed, basically, the state where the setting update display flag is set to "1" is not set. However, when the supply of the operating power to the main CPU 63 is stopped in the situation where the set value updating process (FIG. 181) is being executed, and then the supply of the operating power to the main CPU 63 is started. In, the setting update display flag is set to "1". The state in which the setting update display flag is set to "1" is maintained until the process of clearing the setting update display flag to "0" is executed in the setting value update process (FIG. 181).

When a negative determination is made in step SB808 because "1" is not set in the game stop flag and the setting update display flag, it is determined whether the setting key insertion portion 68a is turned on by using the setting key. (Step SB809). When the setting key insertion unit 68a is turned on by using the setting key (step SB809: YES), the setting confirmation process is executed (step SB810). The processing contents of the setting confirmation processing are the same as the setting confirmation processing (FIG. 166) in the forty-ninth embodiment. Note that in the present embodiment, even if the supply of operating power is stopped while the process for confirming the setting is being executed, the setting confirmation is performed unless the “setting confirmation operation” is performed when the supply of the operating power is restarted. Processing is not executed.

When the setting key insertion unit 68a has not been turned on using the setting key (step SB809: NO), the normal recovery command is transmitted to the voice emission control device 81 (step SB811). The contents of the processing executed by the voice emission control device 81 when the normal recovery command is received are the same as in the forty-ninth embodiment.

On the other hand, when it is determined in step SB807 that the reset button 68c has been pressed, and it is determined that the setting key insertion portion 68a has been turned ON using the setting key (steps SB807 and SB812). : YES), the set value update processing is executed (step SB813). That is, in the present embodiment, even if the setting update display flag in the work area 221 for specific control is set to "1", the "setting change operation" is not performed at the start of supplying the operating power to the main CPU 63. As long as the setting value update process is not executed. Details of the setting value update processing will be described later.

If it is determined in step SB807 that the reset button 68c has been pressed and it is determined that the setting key insertion unit 68a has not been turned on using the setting key (step SB812: NO), identification It is determined whether or not "1" is set to the game stop flag or the setting update display flag in the control work area 221 (step SB814).

When "1" is not set in both the game stop flag and the setting update display flag (step SB814: NO), the first RAM clearing process is executed (step SB815). In the first RAM clearing process, as in the RAM clearing process (step SA416) in the forty-fifth embodiment, an area in which the setting value information indicating the setting state of the pachinko machine 10 is set in the work area 221 for specific control ( That is, except for the setting reference area 341), the work area 221 for the specific control is cleared to "0" and the initial setting is executed. As a result, the area indicating whether or not the winning/winning lottery mode is the high-probability mode is cleared to "0". The mode is a low probability mode. In addition, the game times are not being executed, the opening/closing execution mode is not being executed, and the general-purpose display unit 38a is not being variably displayed, and the general electric accessory 34a is in the closed state. It becomes a situation. Further, since the hold storage area 65a and the universal electric power reserve area 65c provided in the work area 221 for specific control are also cleared to "0", the reserved information for the special figure display section 37a is deleted and the general figure display section is deleted. The hold information for 38a is deleted. Further, the setting update display flag and the setting confirmation display flag provided in the specific control work area 221 are cleared to "0". In addition, the setting update area 342 provided in the specific control work area 221 is cleared to “0”. In the first RAM clearing process, the stack area 222 for specific control is cleared to "0" and the initial setting is executed. Further, in the first RAM clearing process, various registers of the main CPU 63 are also cleared to “0” and then the initial setting is executed. In this initial setting, the same processing as the internal function register setting processing in step SB802 is executed. The process for clearing “0” and the process for initial setting are not executed for the work area 223 for non-specific control and the stack area 224 for non-specific control.

After that, a return command at the time of clear is transmitted to the voice emission control device 81 (step SB816). The contents of the processing executed by the voice emission control device 81 when the clear return command is received are the same as those in the forty-ninth embodiment.

When the process of step SB810 is executed, the process of step SB811 is executed, the process of step SB813 is executed, or the process of step SB816 is executed, the check area provided in the work area 221 for specific control is being checked. Information corresponding to the initial check period (specifically, 5 seconds) is set in the counter (step SB817). The value set in the checking counter is decremented by 1 each time the second timer interrupt process (FIG. 134) is activated, as in the 35th embodiment. When the value of 1 or more is set in the checking counter, the check display is continued on the first to fourth notification display devices 201 to 204 as in the 35th embodiment.

According to the above configuration, when the supply of the operating power to the main CPU 63 is started, the processing at the start of the supply of the operating power (step SB801 to step SB818, step SB823 to step SB826) is completed in the main CPU 63. The initial check period is started later and before the residual process (steps SB819 to SB822) is started. Accordingly, since it is not necessary to control the initial check period in the situation where the processing at the start of supplying the operating power is executed, the processing load in the situation where the processing at the start of supplying the operating power is executed is reduced. It becomes possible.

Further, while the setting confirmation process (step SB810) and the setting value update process (FIG. 181) are executed as the process (step SB801 to step SB818, step SB823 to step SB826) at the start of supplying the operating power, The initial check period starts after the process at the start of supplying the operating power is completed. Accordingly, even if the check display is performed on the first to fourth notification display devices 201 to 204 during the initial check period, the set values are displayed using the first to fourth notification display devices 201 to 204. It becomes possible not to affect.

Then, the start-up processing flag in the work area 221 for specific control is cleared to "0" (step SB818). When the first timer interrupt process (FIG. 133) is started by clearing the start-up processing flag “0”, a negative determination is made in step S8906, and thus not only the processes of steps S8901 to S8905 The processing of steps S8907 to S8920 will be executed, and the state where the processing for advancing the game is not executed is released. In step SB818, the power failure flag in the specific control work area 221 is also cleared to "0".

After that, the process proceeds to the residual processing of steps SB819 to SB822. In other words, the main CPU 63 is configured to periodically execute the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134), but between the one timer interrupt process and the next timer interrupt process. There will be some residual time. This remaining time will vary depending on the processing completion time of each timer interrupt processing, but the remaining processing of step SB819 to step SB822 is repeatedly executed using this irregular time. In this respect, it can be said that the residual processing of steps SB819 to SB822 is non-periodic processing that is performed non-periodically. In steps SB819 to SB822, the same processes as steps S113 to S116 of the main process (FIG. 9) in the first embodiment are executed.

In the main processing (FIG. 179), when a negative determination is made in any of steps SB804 to SB806, that is, when the power failure flag is not set to "1", the checksums do not match, or the set value is abnormal. If it is, the game stop flag in the specific control work area 221 is set to "1" (step SB823). As described above, by setting the game stop flag to "1", the processes of steps S8901 to S8905 are executed in the first timer interrupt process (FIG. 133), while the positive determination is made in step S8906. The processes of steps S8907 to S8920 are not executed. As a result, when the power failure flag is not set to “1” because the power failure process was not properly performed at the previous power shutdown, the work area 221 for the specific control and the stack area 222 for the specific control are If at least one of the checksums does not match due to the change in the information storage state since the last power-off, or if the set value is abnormal, power failure monitoring, updating of various counters and illegal operation While the processing for monitoring is executed, the processing for advancing the game is not executed.

Then, it is determined whether or not the reset button 68c has been pressed (step SB824). If the reset button 68c has not been pressed (step SB824: NO), an abnormal command indicating that an abnormality has occurred with respect to the power failure flag, the checksum, or the set value at the start of supplying the operating power is transmitted to the sound emission control device 81. (Step SB825). Upon receiving the abnormal command, the sound emission control device 81 causes the display light emitting unit 53 to emit light in a manner corresponding to the information abnormality at the time of starting the supply of the operating power, and the speaker unit 54 "Please change the setting." Is output. Moreover, the character image "Please change the setting." is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are ended when the supply of operating power to the pachinko machine 10 is stopped. However, even if the supply of the operating power to the pachinko machine 10 is temporarily stopped, the above notification is given when the supply of the operating power to the pachinko machine 10 is restarted until the setting value updating process (FIG. 181) is executed. It will be restarted.

After that, the external output process at the time of abnormality is executed (step SB826). In the external output process at the time of abnormality, a process for externally outputting an abnormality signal to the management computer of the game hall is executed. In this case, the signal output of the abnormal signal is performed over a predetermined period (for example, 100 milliseconds). However, the present invention is not limited to this, and in a situation in which an event that triggers the execution of the process of step SB826 occurs, the abnormal signal continues to be output, and an event that triggers the execution of the process of step SB826 occurs. The configuration may be such that the output of the abnormal signal is stopped when the situation is not met. Further, the abnormal signal may be output not only in step SB826 but also by other processing. For example, in the fraud detection process (step S8905) of the first timer interrupt process (FIG. 133), even when it is specified that a fraud of the monitoring target (illegal radio wave detection or fraudulent magnetism detection) occurs, the abnormal signal is generated It is output externally. However, the configuration is not limited to the configuration in which the abnormal signal is also used as described above, and the abnormal signal dedicated to step SB826 may be externally output.

If the reset button 68c has been pressed (step SB824: YES), it is determined whether the setting key insertion unit 68a has been turned on using the setting key (step SB812). When the reset button 68c is pressed and the setting key insertion portion 68a is turned on using the setting key (steps SB812 and SB824: YES), the set value updating process is executed (step SB813). That is, when the operating power is supplied to the main CPU 63 in the situation where the “setting change operation” is being performed, an abnormality has occurred in the main RAM 65, and the result is NO in any of steps SB804 to SB806. Even if the determination is made, the set value updating process (FIG. 181) is executed. Thereby, it becomes possible to give priority to the change of the set value.

On the other hand, when the reset button 68c is pressed but the setting key insertion part 68a is not turned on (step SB824: YES, step SB812: NO), the game stop flag or the setting update in the specific control work area 221. It is determined whether "1" is set in the display flag (step SB814). In the process of step SB814 after the game stop flag is set to "1" in step SB823, since the game stop flag is set to "1" as a matter of course, a positive determination is made in step SB814. In this case, an abnormal command is transmitted to the sound emission control device 81 in step SB825, and an abnormal signal is externally output in step SB826. After that, the process proceeds to the residual process of steps SB819 to SB822 without executing the processes of step SB817 and step SB818.

That is, when an abnormality related to the power failure flag, the checksum, and the set value occurs and a negative determination is made in any of steps SB804 to SB806, the operation to the main CPU 63 is performed in the state where the "RAM clear operation" is performed. The first RAM clearing process (step SB815) is not executed even if the power supply is started. The first RAM clearing process is also performed when the supply of operating power to the main CPU 63 is started in the situation where the game stop flag is set to "1" and the "RAM clear operation" is being performed. (Step SB815) is not executed. As a result, even if the supply of operating power to the main CPU 63 is started while the "RAM clear operation" is being performed, the state in which the game stop flag is set to "1" can be prevented from being resolved. It will be possible. On the other hand, when the "setting change operation" is performed, the setting value update processing (FIG. 181) is executed regardless of whether the game stop flag is set to "1" and the details are As will be described later, the game stop flag is cleared to "0" in the initial setting at the start of the set value updating process (FIG. 181). As a result, it becomes necessary to execute the set value updating process (FIG. 181) in order to cancel the state in which the game stop flag is set to "1". Therefore, when the information abnormality of the work area 221 for specific control occurs, not only the process for initializing the work area 221 for specific control, but also the resetting of the set value can be required. ..

Here, when it is determined in step SB807 that the reset button 68c is not pressed, "1" is set in the game stop flag or the setting update display flag in the work area 221 for specific control in step SB808. If it is determined that the abnormality command is transmitted to the sound emission control device 81 in step SB825, the abnormality signal is externally output in step SB826. After executing these processes, the process proceeds to the residual process of steps SB819 to SB822 without executing the processes of steps SB817 and SB818. Further, when it is determined in step SB807 that the reset button 68c has been pressed and it is determined in step SB812 that the setting key insertion part 68a has not been turned on (that is, when the "RAM clear operation" is performed). ), even if "1" is set to the game stop flag or the setting update display flag in the work area 221 for specific control, an affirmative decision is made in step SB814, and a voice emission is carried out in step SB825. An abnormal command is transmitted to the control device 81, and an abnormal signal is externally output in step SB826. After executing these processes, the process proceeds to the residual process of steps SB819 to SB822 without executing the processes of steps SB817 and SB818.

Next, with reference to the time chart of FIG. 180, a description will be given of the state of the subsequent processing when the supply of operating power to the main CPU 63 is stopped in the situation where the setting value update processing (FIG. 181) is being executed. .. FIG. 180(a) shows a period in which the power of the pachinko machine 10 is in an ON state, and FIG. 180(b) shows the processing (step SB801 to step SB818, step SB823 to step SB826) at the start of supply of operating power. 180C shows a period during which the process is executed, and FIG. 180C shows a period during which the process after the process at the start of the supply of the operating power (step SB801 to step SB818, step SB823 to step SB826) is completed, FIG. 180(d) shows the period during which the set value update processing (FIG. 181) is being executed, and FIG. 180(e) shows that the setting update display flag in the specific control work area 221 is set to “1”. 180(f) shows a period in which the start-up processing flag in the work area 221 for specific control is set to "1", and FIG. 180(g) shows an abnormal signal output to the outside. Indicates the period.

At timing t1, the pachinko machine 10 is turned on as shown in FIG. 180(a). In this case, the power-on operation of the pachinko machine 10 is performed in the situation where the “setting change operation” is performed. At the timing of t1, as shown in FIG. 180(b), the main CPU 63 starts the process of starting the supply of the operating power (steps SB801 to SB818, step SB823 to step SB826), and FIG. As shown in (), "1" is set to the in-start-up processing flag in the work area 221 for specific control.

Thereafter, at the timing of t2, the set value updating process (FIG. 181) is started as shown in FIG. 180(d). In this case, “1” is set to the setting update display flag in the specific control work area 221 as shown in FIG. 180(e) at the timing of t2.

Thereafter, as shown in FIG. 180(d), the power of the pachinko machine 10 is turned off at the timing of t3 which is a state in which the setting value update processing (FIG. 181) is being executed, and thus the main CPU 63 is instructed. The supply of operating power of is stopped. Therefore, as shown in FIG. 180(b), the process at the start of supplying the operating power (steps SB801 to SB818, step SB823 to step SB826) is completed, and the set value update process (step SB(d) is performed as shown in FIG. 180(d)). 181) ends.

After that, at the timing of t4, the power-on operation of the pachinko machine 10 is performed again as shown in FIG. 180(a). In this case, the power-on operation of the pachinko machine 10 is performed while the “RAM clear operation” is performed. At the timing of t4, as shown in FIG. 180(b), the main CPU 63 starts the process (steps SB801 to SB818, step SB823 to step SB826) at the start of supplying the operating power. In addition, as shown in FIGS. 180(e) and 180(f), both the setting update display flag and the startup processing flag in the work area 221 for specific control continue to be set to “1” before the supply of the operating power is stopped last time. Is set.

This time, since the power-on operation of the pachinko machine 10 is performed in the situation where the "RAM clear operation" is performed in the situation where the setting update display flag is set to "1", the first RAM clear process (step SB815). 180) is not executed, the external output of the abnormal signal is performed for a predetermined period (for example, 100 milliseconds) from timing t5 to timing t7 as shown in FIG. 180(g). Further, the abnormality notification based on the transmission of the abnormality command is started at the timing of t5.

As shown in FIG. 180(b), the process (step SB801 to step SB818, step SB823 to step SB826) at the start of supply of the operating power started at the timing of t4 ends at the timing of t6. Then, at the timing of t6, the process after the process (step SB801 to step SB818, step SB823 to step SB826) at the time of starting the supply of the operating power is completed is started.

In this case, since the start-up processing flag in the work area 221 for specific control is set to "1" as shown in FIG. Also, the processing for monitoring the power failure, updating various counters, and monitoring for fraud is executed, but the processing for advancing the game is not executed. After that, as shown in FIG. 180(a), the power of the pachinko machine 10 is turned off at the timing of t8, and the supply of the operating power to the main CPU 63 is stopped. Further, at the timing of t8, the processing after the supply ends as shown in FIG. 180(c).

After that, at the timing of t9, the power-on operation of the pachinko machine 10 is performed again as shown in FIG. 180(a). In this case, the power-on operation of the pachinko machine 10 is performed in the situation where the “setting change operation” is performed. At the timing of t9, as shown in FIG. 180(b), the main CPU 63 starts the process (steps SB801 to SB818, step SB823 to step SB826) at the start of supply of operating power. In addition, as shown in FIGS. 180(e) and 180(f), both the setting update display flag and the startup processing flag in the work area 221 for specific control continue to be set to “1” before the supply of the operating power is stopped last time. Is set.

After that, the set value updating process (FIG. 181) is executed as shown in FIG. 180(d) from the timing of t10 to the timing of t11. In this case, the setting value updating process (FIG. 181) ends normally. The setting update display flag is cleared to "0" as shown in FIG. 180(e) at the timing t11 which is the end timing. Further, at the timing of t11, the process at the start of supply of the operating power (steps SB801 to SB818, step SB823 to step SB826) ends as shown in FIG. 180(b). As a result, at the timing of t11, the start-up processing flag is cleared to "0" as shown in FIG. 180(f). Then, at the timing of t11, as shown in FIG. 180(c), the processing after the processing at the start of the supply of the operating power (steps SB801 to SB818, step SB823 to step SB826) is started is started. In this case, since the start-up processing flag has already been cleared to "0", when the first timer interrupt processing (FIG. 133) is activated, processing for power failure monitoring, updating various counters, and illegal monitoring Not only that, processing for advancing the game is executed.

When the supply of operating power to the main CPU 63 is stopped in the situation where the setting value updating process (FIG. 181) is executed as described above, when the supply of operating power to the main CPU 63 is restarted. Unless the "setting change operation" is performed, in the process (step SB801 to step SB818, step SB823 to step SB826) at the time of starting the supply of the operating power, the abnormal command is transmitted to the sound emission control device 81 and the abnormal signal is externally output. Even if the "RAM clear operation" is performed, the first RAM clear process (step SB815) is not executed. Even if the "setting confirmation operation" is performed, the setting confirmation process ( Step SB810) is never executed. Furthermore, when the abnormal command is transmitted to the sound emission control device 81 and the abnormal signal is output to the outside, a process of clearing the start-up processing flag in the work area 221 for specific control to "0" (step) Since the residual processing (step SB819 to step SB822) is executed without executing SB818), power failure monitoring, updating of various counters, and unauthorized monitoring are performed even if the first timer interrupt processing (FIG. 133) is activated. While the processing for is executed, the processing for advancing the game is not executed. As a result, when the supply of operating power to the main CPU 63 is stopped in the situation where the setting value updating process (FIG. 181) is being executed, the main CPU 63 is not changed in the situation where the “setting change operation” is performed. It is necessary to restart the supply of operating power and execute the set value updating process (FIG. 181). Therefore, it becomes possible to surely change the set value.

Next, the setting value update processing in this embodiment executed in step SB813 of the main processing (FIG. 179) will be described with reference to the flowchart in FIG. Note that the processing of steps SB901 to SB918 in the setting value update processing is executed by using the program for specific control and the data for specific control in the main CPU 63.

First, the OFF confirmation flag 361 is set to "1" (step SB901). The OFF confirmation flag 361 is provided in the work area 221 for specific control as shown in the explanatory view of FIG. Even in the present embodiment, in the setting value updating process (FIG. 18 1 ), the value of the setting updating area 342 of the work area 221 for specific control, that is, the setting value to be updated is 1 each time the reset button 68c is pressed. Is added. In this case, when the reset button 68c is changed from the non-operated state to the operated state in order to add only “1” to the set value to be updated for one pressing operation of the reset button 68c, that is, When the detection signal from the detection sensor that detects the operation of the reset button 68c is switched from the operation non-detection state to the operation detection state, the value of the setting update area 342 is incremented by 1 to set the update target setting value. 1 is added.

In the configuration, the OFF confirmation flag 361 indicates whether or not it is the timing when the pressing operation of the reset button 68c is started in the case of confirming whether or not the reset button 68c is pressed in the set value updating process (FIG. 181). This is a flag for confirmation. When it is determined that the reset button 68c is pressed after performing the determination processing (step SB910) of whether or not the reset button 68c is pressed in the set value update processing (FIG. 181), “1 "Is set or the set state of "1" is maintained, and when it is determined that the reset button 68c is not pressed, "0" is cleared or the state of "0" is maintained.

Here, the set value updating process (FIG. 181) is executed on condition that it is determined in step SB807 or step SB824 of the main process (FIG. 179) that the reset button 68c is pressed, as already described. In step SB807 or step SB824, the main CPU 63 directly monitors the input port to which the detection signal from the detection sensor that detects the presence/absence of the pressing operation of the reset button 68c is input to determine whether or not the reset button 68c is pressed. Determine whether. In this case, instead of confirming the start timing and the end timing of the pressing operation of the reset button 68c, it is confirmed whether the reset button 68c is in the pressed state. Therefore, in step SB807 or step SB824, a positive determination is made when the signal corresponding to the pressing operation of the reset button 68c is input to the input port without confirming the OFF confirmation flag 361.

However, in the configuration, the end timing of the pressing operation of the reset button 68c when the power of the pachinko machine 10 for turning on the set value update processing (FIG. 181) and the start timing of the set value update processing (FIG. 181) are set. Depending on the relationship, there may be a case where the pressing operation triggers the addition of one set value to be updated and a case where the pressing operation does not trigger the addition. Then, when the power of the pachinko machine 10 is turned on, the update mode of the set value to be updated changes depending on the end timing of the pressing operation of the reset button 68c, which deteriorates the operability. On the other hand, in the configuration in which the set value to be updated is incremented by 1 when it is determined that the reset button 68c is pressed while the OFF confirmation flag 361 is set to “0”, the set value update process When (FIG. 181) is started, the OFF confirmation flag 361 is set to “1” in step SB901 which is executed prior to the process of determining whether or not the reset button 68c is pressed. By doing so, it becomes possible to prevent the set value to be updated from being incremented by 1 due to the pressing operation of the reset button 68c when the power of the pachinko machine 10 is turned on.

After the processing of step SB901 is executed, interrupt permission is set (step SB902). As a result, the first timer interrupt process (FIG. 133) is interrupted and activated in the first interrupt cycle, and the second timer interrupt process (FIG. 134) is interrupted and activated in the second interrupt period. In the present embodiment, similar to the forty-ninth embodiment, in the processing at the start of supply of operating power (steps SB801 to SB818, step SB823 to step SB826), the first timer interrupt processing (FIG. 133) and the first timer interrupt processing are basically performed. The interrupt of the 2-timer interrupt process (FIG. 134) is prohibited, and the interrupt is permitted in the setting confirmation process (step SB810) and the set value update process (FIG. 181). Therefore, in the situation where the setting confirmation process (step SB810) and the set value update process (FIG. 181) are not executed in the process (step SB801 to step SB818, step SB823 to step SB826) at the start of supplying the operating power, Execution of the 1st timer interrupt process (FIG. 133) and the 2nd timer interrupt process (FIG. 134) is prohibited, and the setting confirmation process (step SB810) or the set value update process (FIG. 181) is executed first. Execution of the timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134) is permitted. However, in the situation where the setting confirmation process (step SB810) or the set value update process (FIG. 181) is being executed, since the startup flag is set to “1”, the first timer interrupt process (FIG. Even if 133) is activated, among the various processes of the first timer interrupt process (FIG. 133), the processes for performing power failure monitoring, updating various counters, and fraudulent monitoring are executed, while progressing the game. The first timer interrupt process (FIG. 133) is terminated without executing the process.

Thereafter, the setting update display flag is set to "1" on condition that the setting update display flag provided in the specific control work area 221 is not set to "1" (step SB903). When the setting update display flag is set to "1", a positive determination is made in step S9003 of the second timer interrupt process (FIG. 134), and the setting process for the fifth display data buffer 275 during the setting update is performed. (Step S9004) is executed. The processing content of the setting processing for the fifth display data buffer 275 during the setting update is the same as that in the 45th embodiment. By executing the process, as shown in the explanatory view of FIG. 124(a), for example, a display indicating that the setting value of the pachinko machine 10 is being updated and selection as an update target of the pachinko machine 10 are made. The displayed set values are displayed on the first to fourth notification display devices 201 to 204.

After that, initial setting at the start is performed (step SB904). In the initial setting, the game stop flag provided in the work area 221 for specific control is cleared to "0". As for the game stop flag, when the power failure flag is not set to "1" because the power failure process was not properly performed at the previous power shutdown (step SB804: NO), the work area 221 for specific control and When the checksums do not match in at least one of the stack areas 222 for specific control because the information storage state has changed since the last power-off (step SB805: NO), or the setting reference area 341 This is a flag that is set to "1" in step SB823 of the main process (FIG. 179) when the set value corresponding to the information stored in is not in the normal range (step SB806: NO). When the game stop flag is set to "1", the processes of steps S8901 to S8905 are executed in the first timer interrupt process (FIG. 133), while the positive determination is made in step S8906 to steps S8907 to step. The process of S8920 is not executed. As a result, when the information abnormality of the main RAM 65 as described above occurs, the processing for performing the power failure monitoring, the updating of various counters and the illegality monitoring is executed, while the processing for advancing the game is executed. Will not be done. By clearing the game stop flag to "0" in the process of step SB904, the state in which the occurrence of the information abnormality of the main RAM 65 is specified is canceled when the set value update process (FIG. 181) is executed. Is possible.

Then, "1" is set in the setting update area 342 (see FIG. 154) in the specific control work area 221 (step SB905). The setting update area 342 is a storage area for storing information on the setting value being updated in the setting value updating process (FIG. 181) as in the 45th embodiment. When the numerical information of “1” is stored in the setting update area 342, the set value of the update target (selection target or change target) is “setting 1”. When the numerical information of “2” is stored in the setting update area 342, the setting value to be updated is “setting 2”. When the numerical information of “3” is stored in the setting update area 342, the setting value to be updated is “setting 3”. When the numerical information of "4" is stored in the setting update area 342, the setting value to be updated is "setting 4". When the numerical information of "5" is stored in the setting update area 342, the setting value to be updated is "setting 5". When the numerical information of “6” is stored in the setting update area 342, the setting value to be updated is “setting 6”.

By setting "1" in the setting update area 342 in step SB905, the setting value to be updated becomes "setting 1". That is, in the present embodiment, the setting value to be updated becomes “setting 1” when the setting value updating process (FIG. 181) is started, whichever setting value the pachinko machine 10 currently has.

After that, the update start command is transmitted to the sound emission control device 81 (step SB906). Upon receiving the update start command, the sound emission control device 81 displays an image showing that the set value update processing (FIG. 181) is being executed, and an image for making it possible to recognize the operation content for changing the set value. , And the display control device 82 so that an image for recognizing the operation content for terminating the set value updating process (FIG. 181) is displayed on the symbol display device 41. This allows the manager of the game hall to recognize that the setting value is being changed, and the operation content and the setting value update process necessary to change the setting value (FIG. 181). It becomes possible for the manager of the game hall to recognize the operation content necessary for ending the game. In addition to or instead of the above-mentioned notification being performed by the symbol display device 41, at least one of the display light emitting unit 53 and the speaker unit 54 may be configured. Further, a configuration may be adopted in which an external output indicating that the set value updating process (FIG. 181) is being executed is performed to a device outside the pachinko machine 10 such as a game hall management computer.

After that, it is determined whether or not the setting value information stored in the setting update area 342 is any of "1" to "6" (step SB907). When it is not any of "1" to "6" (step SB907: NO), "1" is set in the setting update area 342 (step SB908). As a result, the setting value to be updated becomes “setting 1”.

When an affirmative determination is made in step SB907 or the processing of step SB908 is executed, it is determined whether the setting key insertion unit 68a has switched from the ON state to the OFF state using the setting key (step SB909). Specifically, it is determined whether the reception state of the signal received from the detection sensor that detects the state of the setting key insertion unit 68a has changed from the reception state corresponding to the ON state to the reception state corresponding to the OFF state. To do.

When a negative determination is made in step SB909, it is determined whether or not the reset button 68c has been pressed (step SB910). Specifically, it is determined whether or not the reset button 68c is pressed by directly monitoring the input port to which the detection signal from the detection sensor that detects whether or not the reset button 68c is pressed. When the reset button 68c has not been pressed (step SB910: NO), the OFF confirmation flag 361 in the work area 221 for specific control is cleared to "0" (step SB911), and the process returns to step SB907.

When the reset button 68c is pressed (step SB910: YES), it is determined whether the value of the OFF confirmation flag 361 in the specific control work area 221 is "0" (step SB912). When the OFF confirmation flag 361 is set to "1" (step SB912: NO), the current confirmation timing is not the start timing of the pressing operation of the reset button 68c, but the pressing operation of the reset button 68c is continued. Since it means that the situation is present, the process returns to step SB907 without adding 1 to the setting value to be updated.

When the value of the OFF confirmation flag 361 is “0” (step SB912: YES), this means that the confirmation timing this time is the start timing of the pressing operation of the reset button 68c. In this case, after the OFF confirmation flag 361 is set to "1" (step SB913), the value of the setting update area 342 is incremented by 1 (step SB914). As a result, each time the reset button 68c is pressed once, the setting value is updated by one step. In addition, when the reset button 68c is not pressed (step SB910: NO), the OFF confirmation flag 361 is set to "1" (step SB912: NO), or the value of the setting update area 342 is set to 1 If it is added (step SB914), the process returns to step SB907, but if it is determined in step SB907 that the value of the setting update area 342 is 7 or more, the setting update area is determined in step SB908. “1” is set in 342. As a result, when the reset button 68c is pressed once in the situation of "setting 6", the process returns to "setting 1".

When it is specified that the setting key insertion unit 68a is switched from the ON state to the OFF state (step SB909: YES), the setting reference area 341 is overwritten with the setting value information stored in the setting update area 342 ( Step SB915). As a result, the setting value information obtained as a result of the update in the setting value update process this time (FIG. 181) is set in the setting reference area 341, and the setting value corresponding to the set information is the current state. It becomes the set value of the pachinko machine 10.

After that, the interruption is prohibited (step SB916). As a result, in the case of ending the set value updating process (FIG. 181) and returning to the process (step SB801 to step SB818, step SB823 to step SB826) at the start of supplying the operating power in the main process (FIG. 179), The interrupts of the 1-timer interrupt processing (FIG. 133) and the 2nd timer interrupt processing (FIG. 134) are prohibited.

After that, the second RAM clearing process is executed (step SB917). In the second RAM clearing process, as in the RAM clearing process (step SA416) in the forty-fifth embodiment, an area in which the setting value information indicating the setting state of the pachinko machine 10 is set in the work area 221 for specific control ( That is, except for the setting reference area 341), the work area 221 for the specific control is cleared to "0" and the initial setting is executed. As a result, the area indicating whether or not the winning/winning lottery mode is the high-probability mode is cleared to "0". The mode is a low probability mode. In addition, the game times are not being executed, the opening/closing execution mode is not being executed, and the general-purpose display unit 38a is not being variably displayed, and the general electric accessory 34a is in the closed state. It becomes a situation. Further, since the hold storage area 65a and the universal electric power reserve area 65c provided in the work area 221 for specific control are also cleared to "0", the reserved information for the special figure display section 37a is deleted and the general figure display section is deleted. The hold information for 38a is deleted. Further, the setting update display flag and the setting confirmation display flag provided in the specific control work area 221 are cleared to "0". In addition, the setting update area 342 provided in the specific control work area 221 is cleared to “0”. Further, the game stop flag provided in the work area 221 for specific control is cleared to "0". In the second RAM clearing process, the stack area 222 for specific control is cleared to "0" and the initial setting is executed. In the second RAM clearing process, various registers of the main CPU 63 are cleared to "0" and then the initial setting is executed. In this initial setting, the same processing as the internal function register setting processing in step SB802 is executed. The process for clearing “0” and the process for initial setting are not executed for the work area 223 for non-specific control and the stack area 224 for non-specific control.

After that, a return command for updating is transmitted to the sound emission control device 81 (step SB918). The contents of processing executed by the voice emission control device 81 when the return command at the time of updating is received are the same as those in the forty-ninth embodiment.

Next, how the set value to be updated is updated will be described with reference to the time chart in FIG. 183. FIG. 183(a) shows a period during which the power of the pachinko machine 10 is in an ON state, FIG. 183(b) shows an operation state of the setting key insertion part 68a, and FIG. 183(c) shows an operation of the reset button 68c. 183(d) shows the period during which the set value update processing (FIG. 181) is being executed, FIG. 183(e) shows the setting status of the OFF confirmation flag 361, and FIG. 183(f) shows the setting status. Indicates the value update timing.

First, a comparative example in which the OFF confirmation flag 361 is not set to "1" when the set value updating process (FIG. 181) is started will be described.

At the timing of t1, as shown in FIG. 183(b), the setting key insertion portion 68a is turned on by using the setting key, and the reset button 68c is pressed as shown in FIG. 183(c). Then, as shown in FIG. 183(a), the power-on operation of the pachinko machine 10 is performed at the timing t2 in which the ON operation of the setting key insertion portion 68a and the pressing operation of the reset button 68c are continued. In this case, since the power-on operation of the pachinko machine 10 is being performed in the situation where the “setting change operation” has been performed, at the timing of t3, as shown in FIG. 183(d), the set value update processing ( 181) is started.

In the comparative example, since the OFF confirmation flag 361 is not set to “1” when the set value updating process (FIG. 181) is started, the value of the OFF confirmation flag 361 is set at the timing of t3 as shown in FIG. 183(e). Is "0". After that, the reset button 68c is pressed with the value of the OFF confirmation flag 361 being "0" at the timing of t4 when the pressing operation of the reset button 68c is continued during the power-on operation. By specifying this, the setting value to be updated is incremented by 1, as shown in FIG. 183(f). At the timing of t4, the OFF confirmation flag 361 is set to "1" as shown in FIG. 183(e).

That is, in the above comparative example, the pressing operation of the reset button 68c at the time of turning on the power is continued even after the start of the set value updating process (FIG. 181), so that the set value to be updated is 1 when the pressing operation is triggered. Will be added. In this case, the manager of the game hall will update the set value of the update target even though he/she does not intend to update the set value of the update target.

Next, a description will be given of the present embodiment in which the OFF confirmation flag 361 is set to “1” when the set value update processing (FIG. 181) is started.

At the timing of t5, the setting key insertion portion 68a is turned on by using the setting key as shown in FIG. 183(b), and the reset button 68c is pressed as shown in FIG. 183(c). Then, as shown in FIG. 183(a), the power-on operation of the pachinko machine 10 is performed at the timing of t6 when the ON operation of the setting key insertion section 68a and the pressing operation of the reset button 68c are continued. In this case, since the power-on operation of the pachinko machine 10 is being performed in the situation where the “setting change operation” has been performed, the set value update processing (shown in FIG. 183(d)) at the timing of t7 ( 181) is started. When the set value updating process (FIG. 181) is started, a process of setting “1” to the OFF confirmation flag 361 is executed in step SB901. Therefore, at the timing of t7, the OFF confirmation flag 361 is set to "1" as shown in FIG. 183(e). Since the timing of setting "1" to the OFF confirmation flag 361 is before the timing of determining whether or not the reset button 68c has been pressed in the set value update processing (FIG. 181), the timing shown in FIG. As shown in (), even if the pressing operation of the reset button 68c during the ON operation of the power source is continued, 1 is not added to the set value to be updated. Thereafter, at the timing of t8, the pressing operation of the reset button 68c is finished as shown in FIG. 183(c), so that the OFF confirmation flag 361 is cleared to “0” as shown in FIG. 183(e).

After that, as shown in FIG. 183(c), the reset button 68c is pressed at each of the timing t9 to the timing t10, the timing t11 to the timing t12, and the timing t13 to the timing t14. In this case, the reset button 68c is pressed while the value of the OFF confirmation flag 361 is "0" at each of the timings t9, t11, and t13. As shown, the set value to be updated is incremented by 1 at each of these timings.

After that, the setting key insertion unit 68a is turned off at the timing of t15 as shown in FIG. 183(b), which causes the setting value updating process (see FIG. 181) at the timing of t15 as shown in FIG. 183(d). ) Ends.

As described above, in the configuration in which the set value to be updated is incremented by 1 when it is determined that the reset button 68c is pressed in the situation where the OFF confirmation flag 361 is set to “0”, the set value update process (FIG. When 181) is started, the OFF confirmation flag 361 is set to "1" in step SB901 which is executed prior to the process of determining whether or not the reset button 68c is pressed. As a result, it becomes possible to prevent the set value to be updated from being incremented by 1 due to the pressing operation of the reset button 68c when the power of the pachinko machine 10 is turned on.

According to this embodiment described in detail above, the following excellent effects are exhibited.

When the set value update process (FIG. 181) is started, the set value is changed from the set value corresponding to a predetermined start. As a result, regardless of the set value to be used before the set value update process (FIG. 181) is started, in the set value update process (FIG. 181), the operation of changing the set value from the set value corresponding to a certain start is performed. Will be possible. Therefore, the work content of the operation of changing the set value becomes easy for the operator to understand.

Specifically, the setting value corresponding to the start is “setting 1” having the lowest advantage. Therefore, when the setting value update process (FIG. 181) is started, the setting value is changed from “setting 1” having the lowest advantage. As a result, even if the manager of the game hall unintentionally terminates the set value update processing (FIG. 181) immediately after the start of the set value update processing (FIG. 181), the setting value with the lowest advantage is set. Therefore, even if the game is started in such a situation, it is possible to prevent an unintended disadvantage from occurring in the game hall.

The work area 221 for specific control is provided with a setting reference area 341 and a setting update area 342. Information corresponding to the setting value to be used is stored in the setting reference area 341, and the setting value update processing is performed. Information corresponding to the setting value being changed in the situation where (FIG. 181) is being executed is stored in the setting update area 342. As a result, while the setting reference information 341 stores and retains the setting value information that was set before the setting value updating process (FIG. 181) was started, the setting value update process (FIG. 181) indicates the target of updating. It is possible to change the set value.

When the supply of the operating power to the main CPU 63 is stopped in the situation where the setting value update process (FIG. 181) is being executed, the game is performed when the supply of the operating power to the main CPU 63 is resumed after that. The regulation state in which the process for advancing is started is not started. This makes it possible to prevent the process for advancing the game from being started even though the set value update process (FIG. 181) has not been completed.

Even when the supply of the operating power to the main CPU 63 is stopped in the situation where the set value updating process (FIG. 181) is being executed, the supply of the operating power to the main CPU 63 is resumed after that. When the "setting change operation" is performed on the above, the above-mentioned restricted state is not obtained. As a result, it becomes possible to prevent the execution of the process for advancing the game from being restricted until the setting value is changed.

Even in the regulated state, power failure monitoring and various counter update processing are executed. As a result, it becomes possible to ensure the execution of the necessary processing even when the progress of the game is restricted as described above. In particular, by executing the power outage monitoring, it is possible to appropriately cope with the power outage even if the progress of the game is restricted.

The regulation state is resumed when the supply of the operating power is resumed even if the supply of the operating power is stopped. As a result, when the set value update process (FIG. 181) is being executed, the supply of the operating power to the main CPU 63 is stopped to restrict the execution of the process for advancing the game. It is possible not to be released only by stopping the supply of.

In the configuration in which the set value to be updated is incremented by 1 when it is determined that the reset button 68c is pressed while the OFF confirmation flag 361 in the work area 221 for specific control is set to "0" When the value update process (FIG. 181) is started, the OFF confirmation flag 361 is set to “1” in step SB901 which is executed before the process of determining whether or not the reset button 68c is pressed. It is a configuration that does. As a result, it becomes possible to prevent the set value to be updated from being incremented by 1 due to the pressing operation of the reset button 68c when the power of the pachinko machine 10 is turned on.

It should be noted that if the supply of the operating power to the main CPU 63 is stopped in the middle of the set value updating process (FIG. 181), and the setting confirmation process ( When step SB810) is executed, the setting update display flag may be cleared to "0" and the execution of the process for advancing the game may not be restricted. By executing the setting confirmation process (step SB810), the setting value of the current usage target is notified, so that the manager of the game hall can grasp the setting value of the usage target. In such a case, even if the execution of the process for advancing the game is not restricted, the game will not be advanced with the set value that is not assumed by the manager of the game hall.

Further, if the supply of the operating power to the main CPU 63 is stopped during the set value updating process (FIG. 181), whether or not the “setting change operation” is performed when the supply of the operating power is resumed thereafter. Alternatively, the setting value update process (FIG. 181) may be forcibly executed regardless of the above. This makes it possible to forcibly change the set value.

Further, when the supply of the operating power to the main CPU 63 is stopped in the middle of the setting confirmation process (step SB810), the execution of the process for advancing the game is restricted when the supply of the operating power is resumed thereafter. It is also possible to adopt a configuration in which the regulation state is set. In this case, when the setting confirmation process (step SB810) is executed when the supply of the operating power is resumed, the regulation state may not be set. In addition to or instead of the configuration, when the supply of the operating power is resumed. When the set value updating process (FIG. 181) is executed, the regulation state may not be set.

Further, if the supply of the operating power to the main CPU 63 is stopped in the middle of the setting confirmation process (step SB810), whether or not the “setting confirming operation” is performed when the supply of the operating power is resumed thereafter. The configuration confirmation process (step SB810) may be forcibly executed regardless of the above. This makes it possible to forcibly confirm the set value.

Further, in the set value update process (FIG. 181), it is specified that the reset button 68c has not been pressed in the preceding process times in two consecutive process times, and the reset button 68c is changed in the subsequent process times. Although the setting value of the selection target is changed when it is specified that the pressing operation is performed, the present invention is not limited to this, and the reset button 68c may be pressed at each of a plurality of past consecutive processing times. Is determined not to be pressed, and the setting value of the selection target is changed when it is specified that the reset button 68c is pressed in one situation or a plurality of consecutive treatments in that situation. It may be configured to be. Even in this case, when the set value updating process (FIG. 181) is started, the reset button 68c is operated by pressing the information regarding the confirmation history of the pressing operation of the reset button 68c in a plurality of past consecutive processing times. By rewriting the information corresponding to the fact that the setting value is updated, the setting value to be selected is changed in the setting value updating process (FIG. 181) by pressing the reset button 68c for starting the setting value updating process (FIG. 181). It becomes possible not to.

<Fifty-fourth embodiment>
In this embodiment, the processing configuration of the main processing executed by the main CPU 63 is different from that in the 53rd embodiment. The configuration different from that of the 53rd embodiment will be described below. The description of the same configuration as that of the 53rd embodiment is basically omitted.

FIG. 184 is a flowchart showing the main processing executed in the main CPU 63 in this embodiment. Note that the processing of steps SC101 to SC128 in the main processing is executed using the program for specific control and the data for specific control in the main CPU 63.

In Step SC101 to Step SC106, the same processing as Step SB801 to Step SB806 of the main processing (FIG. 179) in the 53rd embodiment is executed. When a positive determination is made in all of steps SC104 to SC106, it is determined whether or not the reset button 68c has been pressed (step SC107). If the reset button 68c is not pressed (step SC107: NO), it is determined whether the setting update display flag in the specific control work area 221 is set to "1" (step SC108). ). When the reset button 68c is not pressed and the setting update display flag is not set to "1" (step SC107 and step SC108: NO), the game stop flag in the work area 221 for specific control is set to "1". It is determined whether or not is set (step SC109). When the game stop flag is set to "1", an abnormal command is transmitted in step SC127, and external output processing at the time of abnormality is executed in step SC128.

When "1" is not set in the game stop flag (step SC109: NO), the process proceeds to step SC110. In steps SC110 to SC112, the same processing as steps SB809 to SB811 of the main processing (FIG. 179) in the 53rd embodiment is executed.

If it is determined in step SC107 that the reset button 68c is pressed, or if it is determined in step SC108 that the setting update display flag is set to "1", the setting key insertion portion 68a is determined in step SC113. It is determined whether or not is ON-operated by using the setting key. Then, when it is determined that the setting key insertion unit 68a is turned on (step SC113: YES), after setting the OFF confirmation flag 361 in the work area 221 for specific control to "1" (step SC114), the setting is performed. A value update process is executed (step SC115). Note that in steps SC116 to SC128, the same processing as steps SB114 to SB826 of the main processing (FIG. 179) in the 53rd embodiment is executed.

That is, in the present embodiment, when the supply of the operating power to the main CPU 63 is stopped during the execution of the setting value update process (step SC115), the situation of “no operation” or the “RAM clear operation” is performed. When the supply of operating power to the main CPU 63 is restarted in the situation, the situation in which the process for advancing the game is blocked is continued as in the 53rd embodiment, while the "setting change operation" is continued. Not only when the supply of the operating power to the main CPU 63 is restarted in the situation where the operation is performed, but also when the supply of the operating power to the main CPU 63 is restarted in the situation where the “setting confirmation operation” is performed. The set value updating process (step SC115) is executed. As a result, when the supply of the operating power to the main CPU 63 is resumed after the supply of the operating power to the main CPU 63 is stopped during the execution of the set value updating process (step SC115), the set value updating process ( It becomes easy to execute step SC115).

In particular, in the "setting change operation", it is necessary to turn on the setting key insertion portion 68a using the setting key and to press the reset button 68c, and to use the setting key in the "setting confirmation operation". In the configuration in which the key insertion portion 68a needs to be turned on, if the setting update display flag is set to "1", the setting key insertion portion 68a is turned on even if the reset button 68c is not pressed. By doing so, the set value updating process (step SC115) is executed. As a result, although the setting value update processing (step SC115) is started by turning on the power of the pachinko machine 10 in the state of performing the "setting change operation", for example, the power is turned off by mistake during the process. In this case, in order to quickly return to the ON state of the power supply after that, the setting key insertion portion 68a is maintained in the ON operation state, and the reset button 68c is not pressed even if the setting operation is performed. The value update process (step SC115) can be executed.

Further, in the present embodiment, when it is determined in step SC112 that the setting key insertion unit 68a is turned on, the work for specific control is performed in step SC114 before the setting value update process (step SC115) is started. The OFF confirmation flag 361 in the area 221 is set to "1". As a result, even if the processing for setting "1" to the OFF confirmation flag 361 is not performed when the setting value update processing (step SC115) is started, the pressing operation of the reset button 68c at the time of the power-on operation is triggered. It is possible to prevent the set value to be updated from being incremented by 1. By the way, in the set value updating process (step SC115) of the present embodiment, the process of step SB901 in the set value updating process (FIG. 181) of the 53rd embodiment described above is not executed and the process of steps SB902 to SB918 is executed. Executed.

In the set value update process (step SC115), it is specified that the reset button 68c has not been pressed in the preceding process times in two consecutive process times, and the reset button 68c is pressed in the subsequent process times. Although the setting value of the selection target is changed when it is specified that the pressing operation is performed, the present invention is not limited to this, and the reset button 68c may be pressed at each of a plurality of past consecutive processing times. Is determined not to be pressed, and the setting value of the selection target is changed when it is specified that the reset button 68c is pressed in one situation or a plurality of consecutive treatments in that situation. It may be configured to be. Even in this case, when the set value updating process (step SC115) is started, the reset button 68c is pressed and operated on the information regarding the confirmation history of the pressing operation of the reset button 68c in a plurality of past consecutive processing times. By rewriting the information corresponding to the fact that the setting value is updated, the setting value to be selected is changed in the setting value updating process (FIG. 181) by pressing the reset button 68c for starting the setting value updating process (FIG. 181). It becomes possible not to.

<55th Embodiment>
In this embodiment, the processing configuration of the main processing executed by the main CPU 63 is different from that in the 49th embodiment. Hereinafter, a configuration different from that of the 49th embodiment will be described. Note that the description of the same configuration as the 49th embodiment is basically omitted.

FIG. 185 is a flowchart showing the main processing executed in the main CPU 63 in this embodiment. The processes of steps SC201 to SC230 in the main process are executed by using the specific control program and the specific control data in the main CPU 63.

First, power-on initialization processing is executed (step SC201). In the power-on initialization process, for example, a predetermined wait time (specifically, 1 second) elapses after the main process is started, and the process waits without proceeding to the next process. In the predetermined period for this weight, the operation start and initial setting of the symbol display device 41 are completed. Also, access to the main RAM 65 is permitted.

Then, the internal function register setting process is executed (step SC202). In the internal function register setting process, as in the 35th embodiment, the interrupt period of the first timer interrupt process (FIG. 133), which is a process that is activated by periodically interrupting the main process, is set to (Specifically, 4 ms), and the interrupt period of the second timer interrupt process (FIG. 188), which is a process that is activated by periodically interrupting the main process, from the first interrupt period. Is set to the second interrupt cycle (specifically, 2 milliseconds) which is a short cycle.

That is, in the present embodiment, as in the 35th embodiment, the first timer interrupt processing (FIG. 133) and the second timer interrupt processing (FIG. 188) are performed so that the interrupt cycle becomes relatively long and short as the timer interrupt processing. And exist. Both the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 188) are activated by interrupting the main process. The second timer interrupt process (FIG. 188) is activated by interrupting the first timer interrupt process (FIG. 133). On the other hand, the first timer interrupt process (FIG. 133) does not start by interrupting the second timer interrupt process (FIG. 188). Further, if both the first interrupt cycle and the second interrupt cycle have passed in a situation where both the first timer interrupt processing (FIG. 133) and the second timer interrupt processing (FIG. 188) are not executed, those cycles The second timer interrupt process (FIG. 188) is started first regardless of the lapsed order of. In this respect, it can be said that the second timer interrupt process (FIG. 188) is a process activated prior to the first timer interrupt process (FIG. 133). However, the configuration is not limited to this, and the first timer interrupt process (FIG. 133) may be activated prior to the second timer interrupt process (FIG. 188).

In the internal function register setting processing, the first interrupt cycle of the first timer interrupt processing (FIG. 133) is set in a predetermined register of the main CPU 63, and the second interrupt cycle of the second timer interrupt processing (FIG. 188) is set. It is set in a specific register of the side CPU 63. Further, in the internal function register setting process, in addition to the setting of the first and second interrupt cycles, the setting process of the numerical range of various counters such as the numerical range of the hit random number counter C1 is executed.

Then, "1" is set to the in-start-up processing flag provided in the work area 221 for specific control (step SC203). As in the 35th embodiment, the start-up processing flag is among the various processes set in the first timer interrupt process (FIG. 133) even if the first timer interrupt process (FIG. 133) is activated. While the power outage monitoring, the processing for updating various counters and the illegality monitoring are executed, the first timer interrupt processing (FIG. 133) should be terminated without executing the processing for advancing the game. This is a flag for specifying by the main CPU 63.

The start-up processing flag is set to "1" when the processing (step SC201 to step SC223) at the start of supplying the operating power is started in the main processing (FIG. 185), and the processing at the start of supplying the operating power. "0" is cleared before (steps SC201 to SC223) are ended and residual processing (steps SC227 to SC230) is started. As in the 35th embodiment, in the first timer interrupt process (FIG. 133), when the start-up processing flag is set to "1", the processes of steps S8907 to S8920 are not executed. Thus, the process for advancing the game in a situation where the process for confirming the setting (step SC213) or the process for updating the setting value (step SC216) is being performed among the processes at the start of supplying the operating power (steps SC201 to SC223). Can be prevented from being executed. On the other hand, as described above, in the first timer interrupt processing (FIG. 133), even if the start-up processing flag is set to "1", by executing the processing of steps S8901 to S8905, the operating power is reduced. In the situation where the setting confirmation process (step SC213) or the set value update process (step SC216) among the processes at the start of supply (step SC201 to step SC223) is being executed, the power failure monitoring is executed, The hit random number counter C1, the big hit type counter C2, the reach random number counter C3, and the random number initial value counter CINI are updated, and further fraud detection is executed.

In particular, even when the start-up processing flag is set to "1", the power failure information storage processing (step S8901) is executed, so that the processing at the start of supplying the operating power (steps SC201 to SC223) is started. Even if a power failure occurs in the situation where the setting confirmation process (step SC213) or the set value update process (step SC216) is executed, the power failure process can be executed for the power failure. In the power failure process, as in the thirty-fifth embodiment, the power failure flag provided in the specific control work area 221 is set to "1", the checksum is calculated, and the calculated checksum is used for the specific control. Since the data is stored in the work area 221 of No. 1, it is possible to prevent the occurrence of an abnormality in the main RAM 65 when the supply of operating power is restarted. As a result, when a power failure occurs in the middle of the setting confirmation process (step SC213) or the set value update process (step SC216), the fact that the power failure occurred in the middle of these setting-related processes is supplied to the next operating power. It is possible to specify at the start.

Incidentally, in the situation where the setting confirmation process (step SC213) or the set value update process (step SC216) is being executed, both the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 188) are performed. Interrupts are not prohibited and can be interrupted at any timing. In this case, when the first timer interrupt process (FIG. 133) or the second timer interrupt process (FIG. 188) is activated in the setting confirmation process (step SC213) or the set value update process (step SC216), The information of the return address of the main process (FIG. 185) for returning after the timer interrupt process that is the activation target is saved is saved in the stack area 222 for specific control, and the timer interrupt process is activated. Information of various registers of the main CPU 63 immediately before is saved in the stack area 222 for specific control. Then, when the timer interrupt process that is the activation target ends, the process returns to the process of the main process (FIG. 185) corresponding to the information of the return address saved in the stack area 222 for specific control, and The information saved in the stack area 222 for specific control is restored to various registers of the main CPU 63.

After that, the display start flag provided in the specific control work area 221 is cleared to "0" (step SC204). The display start flag specifies in the main CPU 63 that the display control of the special figure display unit 37a and the general figure display unit 38a should be started after the supply of the operating power to the main CPU 63 is started. It is a flag for.

After that, in Step SC205 to Step SC225, the same processing as Step SB104 to Step SB124 of the main processing (FIG. 165) in the forty-ninth embodiment is executed. In this case, the processing content executed in the main processing (FIG. 185) is the 49th operation described above due to the combination of the situation when the supply of the operating power last time and the operation content when the supply of the operating power this time is started. Similar to the embodiment, the processing content shown in the explanatory diagram of FIG. 171 is obtained. For example, when the power failure process is executed in a situation where neither the setting confirmation process (step SC213) nor the set value update process (step SC216) is executed, or the setting confirmation process (step SC213) is executed. In the case where the power failure process is executed under the above condition, and the “RAM clear operation” is performed when the supply of the operating power is subsequently restarted, the first RAM clear process (step 185) is performed in the main process (FIG. 185). SC218) is executed. In addition, when the power outage process is executed in the situation where the set value update process (step SC216) is being executed, the set value update process ( In step SC216, the second RAM clearing process (step SB313 in FIG. 167 in the forty-ninth embodiment) is executed, and the power failure process is executed in the situation where the set value updating process (step SC216) is not executed. Even in such a case, if the “setting change operation” is performed when the supply of the operating power is subsequently restarted, the second RAM clearing process (see FIG. 49 in the forty-ninth embodiment in the setting value updating process (step SC216)) is performed. Step SB313) is executed.

In the first RAM clearing process and the second RAM clearing process, the clear target area 371 in the specific control work area 221 is cleared to “0” and the initial setting is executed, while the clear target non-clear area 372 in the specific control work area 221 is executed. For 0, clearing "0" and initial setting are not executed. FIG. 186 is an explanatory diagram for explaining the clear target area 371 and the non-clear target area 372 provided in the work area 221 for specific control.

Also in the present embodiment, as in the first embodiment, even when the supply of operating power to the main CPU 63 is stopped because the power of the pachinko machine 10 is OFF, the power supply/launch control is performed. Backup power is supplied to the main RAM 65 from the power supply unit for power interruption provided in the device 78 as power for storing and holding. By supplying backup power to the main RAM 65 in this manner, the work area 221 for specific control, the stack area 222 for specific control, the work area 223 for non-specific control, and the stack area 224 for non-specific control are provided. Backup power is also supplied. Then, the backup power is supplied to the work area 221 for specific control, so that the backup power is supplied to the clear target area 371 and the non-clear target area 372. As a result, backup power is supplied to the clear target area 371 and the non-clear target area 372 even when the supply of operating power to the main CPU 63 is stopped because the power of the pachinko machine 10 is OFF. Information is stored and held in the clear target area 371 and the non-clear target area 372.

The clear target area 371 includes the second display data buffer 272, the fourth display data buffer 274, and the fifth display data buffer 275. The second display data buffer 272 is an area in which display data for causing the special figure reservation display unit 37b to perform a predetermined display is set, as in the 33rd embodiment. When the pending information for the special drawing display unit 37a is newly stored in the pending storage area 65a in the pending information acquisition processing (step S401) in the special drawing special power control processing (FIG. 12), the first timer interrupt processing In the display control process (step S8915) in (FIG. 133), the display data corresponding to the number of the hold information for the special figure display unit 37a stored in the hold storage area 65a after the storage is the second display data buffer 272. Is set to. Further, in the data setting process (step S502) in the special figure variation start process (FIG. 13), when the hold information for the special figure display portion 37a is exhausted as an opportunity to execute the game, the first timer interrupt process ( In the display control process (step S8915) in FIG. 133), display data corresponding to the number of reservation information for the special figure display unit 37a stored in the reservation storage area 65a after the digestion is stored in the second display data buffer 272. Is set.

The fourth display data buffer 274 is an area for storing display data for causing the universal figure suspension display section 38b to perform a predetermined display, as in the 33rd embodiment. When the hold information for the universal figure display unit 38a is newly stored in the universal figure retaining area 65c in the universal figure universal communication control process (step S8914) in the first timer interrupt process (FIG. 133), the first timer In the display control process (step S8915) in the interrupt process (FIG. 133), the display data corresponding to the number of the reservation information for the universal figure display unit 38a stored in the universal communication suspension area 65c after the storage is displayed in the fourth display. It is set in the data buffer 274. Further, the hold information for the universal figure display unit 38a is consumed in the universal figure universal communication control process (step S8914) in the first timer interrupt process (FIG. 133) as an execution trigger for the variable display times of the universal diagram display unit 38a. In this case, in the display control process (step S8915) in the first timer interrupt process (FIG. 133), the number corresponds to the number of reservation information for the universal figure display unit 38a stored in the universal communication reservation area 65c after the digestion. The display data to be set is set in the fourth display data buffer 274.

The fifth display data buffer 275 is an area in which display data for causing the first to fourth notification display devices 201 to 204 to perform a predetermined display is set, as in the 33rd embodiment. The setting of the display data in the fifth display data buffer 275 is executed in step SC403, step SC405 and step SC406 in the second timer interrupt process (FIG. 188) described later.

In addition to the second display data buffer 272, the fourth display data buffer 274, and the fifth display data buffer 275, the clear target area 371 includes a hold storage area 65a for storing hold information for the special figure display portion 37a and a normal storage area. It includes a general electric power reservation area 65c in which reservation information for the diagram display unit 38a is stored. Therefore, when the first RAM clearing process or the second RAM clearing process is executed, the pending information for the special figure display unit 37a and the pending information for the general figure display unit 38a are erased. In this case, the clear target area 371 includes the second display data buffer 272 and the fourth display data buffer 274 as described above. As a result, when the holding storage area 65a is initialized and the holding information for the special figure display unit 37a becomes 0, the display content of the special figure holding display unit 37b is also held for the special figure display unit 37a. It becomes possible to set the display content to be 0 pieces of information, and when the holding information for the figure display unit 38a becomes 0 by the initialization of the ordinary electricity holding area 65c, the figure holding is performed. The display content of the display unit 38b can also be set to the display content in which there is no reservation information for the general figure display unit 38a.

In addition, in the first to fourth notification display devices 201 to 204, basically, after the processing (step SC201 to step SC223) at the time of starting the supply of the operating power is finished, the base is basically the same as in the above-mentioned forty-ninth embodiment. Although the value information is displayed, if the setting confirmation process (step SC213) is executed in the process (step SC201 to step SC223) at the time of starting the supply of the operating power, the current pachinko machine 10 If the set value is displayed and the set value update process (step SC216) is executed, the set value in the middle of updating is displayed, and the process at the start of supply of operating power (step SC201 to step SC223) is completed. In some cases, a check display is displayed. That is, in the first to fourth notification display devices 201 to 204, when the supply of the operating power is restarted, information different from the information of the base value displayed before the supply of the operating power is stopped is displayed. Will be displayed. Therefore, even if the fifth display data buffer 275 is initialized when the first RAM clearing process or the second RAM clearing process is executed, no problem occurs in the display contents of the first to fourth notification display devices 201 to 204. ..

In addition to the above areas, the clear target area 371 includes an area for special map/special electric control and an area for general/universal electric power control. Therefore, when the first RAM clearing process or the second RAM clearing process is executed, the win/loss lottery mode becomes the low probability mode regardless of the win/loss lottery mode immediately before the supply of the operating power to the pachinko machine 10 is stopped. In addition, the game times are not being executed, the opening/closing execution mode is not being executed, and the general-purpose display unit 38a is not being variably displayed, and the general electric accessory 34a is in the closed state. It becomes a situation. Further, the setting update display flag and the setting confirmation display flag provided in the specific control work area 221 are cleared to "0", and the setting update area 342 provided to the specific control work area 221 is cleared to "0". To be done. Further, the stack area 222 for specific control is cleared to “0” and the initial setting is executed. Also, after the various registers of the main CPU 63 are cleared to "0", the initial setting is executed. In this initial setting, the same processing as the internal function register setting processing in step SC202 is executed.

The processing contents of the first RAM clearing process are the same as the processing contents of the second RAM clearing process in the set value updating process, but a part of these processing contents may be different. For example, in the first RAM clear processing, the area to be cleared to "0" and to be initialized may not be the target to be cleared to "0" and initialized in the second RAM clear processing, and may be set to "0" in the second RAM clear processing. The area targeted for clearing and initial setting may not be targeted for clearing and initializing “0” in the first RAM clear processing.

The non-clearing target area 372 includes the first display data buffer 271, the third display data buffer 273, and the initial display completion flag 373. The first display data buffer 271 is an area for storing display data for causing the special figure display unit 37a to perform a predetermined display, as in the 33rd embodiment. In step S513 of the special figure fluctuation start process (FIG. 13), the process for starting the variable display of the picture is executed in the special figure display portion 37a, whereby the display control process (FIG. 133) in the first timer interrupt process (FIG. 133) is executed. In step S8915), the display data corresponding to the display at the start of fluctuation of the special figure display portion 37a is set in the first display data buffer 271. Further, the processing for updating the display content of the special figure display unit 37a is executed in the special figure changing process (step S407) in the special figure special electric control process (FIG. 12), whereby the first timer interrupt process (FIG. In the display control process (step S8915) in 133), the display data for advancing the variable display of the picture on the special figure display portion 37a is set in the first display data buffer 271. Further, in the special figure special electric control process (FIG. 12) during the special figure finalizing process (step S408), the display content of the special figure display portion 37a is changed to the hit determination process (step S504) and the distribution determination process (step S504) in the current game time. By executing the processing for making the display content corresponding to the processing result of step S506), the special figure display portion 37a is played this time by the display control processing (step S8915) in the first timer interrupt processing (FIG. 133). The display data for displaying the result corresponding to the number of times is set in the first display data buffer 271. The display data set in this case becomes the display data selected in step S507 or step S509 of the special figure variation start process (FIG. 13) at the start of the current game time. In addition, the display data set in this case is stored and held in the first display data buffer 271 until the special figure display portion 37a becomes a situation where a new game time is started.

The third display data buffer 273 is an area in which display data for causing the general-picture display section 38a to perform a predetermined display is stored as in the 33rd embodiment. In the universal figure universal communication control process (step S8914) in the first timer interrupt process (FIG. 133), the process for starting the variable display of the pattern is executed in the universal pattern display portion 38a, whereby the first timer interrupt process ( In the display control process (step S8915) in FIG. 133), the display data corresponding to the display at the start of variation of the universal figure display unit 38a is set in the third display data buffer 273. Further, the processing for updating the display content of the universal figure display unit 38a is executed in the universal figure universal communication control process (step S8914) in the first timer interrupt process (FIG. 133), whereby the first timer interrupt process ( In the display control process (step S8915) in FIG. 133), the display data for advancing the variable display of the picture on the universal figure display portion 38a is set in the third display data buffer 273. In addition, the display content of the universal figure display unit 38a in the universal figure universal communication control process (step S8914) in the first timer interrupt process (FIG. 133) corresponds to the result of the universal network open lottery in the current variable display times. By executing the processing for the above, in the display control processing (step S8915) in the first timer interrupt processing (FIG. 133), the general figure display unit 38a is caused to perform the display corresponding to the result of the variable display this time. Display data is set in the third display data buffer 273. The display data set in this case is stored and held in the third display data buffer 273 until a situation in which a new variable display time is started on the universal figure display section 38a is reached.

The initial display completed flag 373 is a flag for the main CPU 63 to specify whether or not the situation is after the initial display of the special figure display portion 37a and the general figure display portion 38a at the factory shipping stage is completed. Since the non-clearing target area 372 includes the initial display completed flag 373, once the initial display of the special figure display portion 37a and the general figure display portion 38a at the shipping stage of the factory is once confirmed, the operation power of It is possible to prevent the initial display from being performed when the supply is restarted.

Since the non-clearing target area 372 includes the first display data buffer 271 and the third display data buffer 273, the supply of operating power is restarted even if the first RAM clearing process or the second RAM clearing process is executed. After the display of the special figure display unit 37a and the general figure display unit 38a is started, the display contents of the special figure display unit 37a and the general figure display unit 38a are displayed before the supply of the operating power is stopped. It is possible to return to. Thereby, even if the player confirms the special figure display section 37a and the general figure display section 38a after the supply of the operating power is restarted, it is determined whether the first RAM clear processing or the second RAM clear processing is executed. Can't do it.

In particular, the second RAM clearing process is executed by the setting value updating process (step SC216) that enables changing the setting value of the pachinko machine 10. Therefore, when the second RAM clearing process is executed, the special figure display unit is displayed. If the display content of at least one of 37a and the universal figure display section 38a becomes the display content corresponding to the execution of the second RAM clearing process or is changed from the display content before the supply of the operating power is stopped, the display content By checking the special figure display section 37a or the general figure display section 38a, the presence or absence of a change in the set value of the pachinko machine 10 can be predicted. On the other hand, even if the second RAM clearing process is executed, the special figure display section 37a and the general figure display section 38a are displayed after the supply of the operating power is started and these special figure display section 37a are started. Also, the display content of the public figure display unit 38a is restored to the display content before the supply of the operating power is stopped. As a result, even if the special figure display unit 37a and the general figure display unit 38a are checked, it is possible to prevent the setting value update processing (step SC216) from being specified.

In addition to the above-described areas, the non-clearing target area 372 includes an area (that is, a setting reference area 341) in which information of setting values indicating the setting state of the pachinko machine 10 is set. Thereby, even if the first RAM clearing process or the second RAM clearing process is executed, the setting value information indicating the setting state of the pachinko machine 10 is maintained as it is. The non-clearing target area 372 also includes a work area 223 for non-specific control and a stack area 224 for non-specific control.

By the way, since backup power is not supplied to the RAM of the sound emission control device 81 and the display control device 82, the pachinko machine 10 is turned off to supply operating power to the sound emission control device 81 and the display control device 82. When stopped, the information stored in the RAMs of the audio emission control device 81 and the display control device 82 is erased. However, when the first RAM clear process and the second RAM clear process are not executed when the supply of the operation power is started, the main CPU 63 stops the supply of the operation power to the sound emission control device 81 to the effect execution state. By transmitting the command for returning to the state immediately before, the content of the effect execution control in the sound emission control device 81 and the display control device 82 is returned to the state immediately before the supply of the operating power is stopped. It will be.

Returning to the explanation of the main process (FIG. 185), after the process of step SC225 is executed, the display start process is executed (step SC226). After that, the residual processing is executed in steps SC227 to SC230. The processing contents of these steps SC227 to SC230 are the same as steps SB125 to SB128 of the main processing (FIG. 165) in the forty-ninth embodiment.

Next, the display start processing executed in step SC226 of the main processing (FIG. 185) will be described with reference to the flowchart in FIG. 187. Note that the processing of step SC301 to step SC305 in the display start processing is executed using the program for specific control and the data for specific control in the main CPU 63.

When "1" is not set in the initial display completed flag 373 (step SC301: NO), the initial display data for special drawing is set in the first display data buffer 271 (step SC302), and the initial for general drawing is set. The display data is set in the third display data buffer 273 (step SC303). Then, "1" is set to the initially displayed flag 373 (step SC304).

By performing display control of the special figure display unit 37a using the initial display data for special figure stored in the first display data buffer 271, the initial display is performed on the special figure display unit 37a. The display content of the initial display on the special figure display part 37a is arbitrary, but for example, all of the plurality of light emitting parts provided in the special figure display part 37a may be in a light emitting state, and the display may be provided on the special figure display part 37a. A configuration may be adopted in which a part of the plurality of light emitting units thus formed are in a light emitting state. When some of the light emitting units are in the light emitting state, the light emitting units that are in the light emitting state and the light emitting units that are maintained in the off state may be alternately arranged in the arrangement order. In addition, the display of the general figure display unit 38a is controlled by using the initial display data for general figure stored in the third display data buffer 273, so that the general figure display unit 38a performs the initial display. The display content of the initial display on the public figure display unit 38a is arbitrary, but, for example, all of the plurality of light emitting units provided on the public figure display unit 38a may be in a light emitting state, and the general figure display unit 38a may be provided. A configuration may be adopted in which a part of the plurality of light emitting units thus formed are in a light emitting state. When some of the light emitting units are in the light emitting state, the light emitting units that are in the light emitting state and the light emitting units that are maintained in the off state may be alternately arranged in the arrangement order.

On the other hand, when "1" is set in the initial display completed flag 373 (step SC301: YES), the processes of step SC302 and step SC303 are not executed. Therefore, the first display data buffer 271 is in a state in which the display data stored immediately before the supply of the operating power is stopped is stored as it is, and the third display data buffer 273 is immediately before the supply of the operating power is stopped. The display data stored in is stored as it is. Further, as described above, the first display data buffer 271 and the third display data buffer 273 are provided in the non-clearing target area 372, so that the main processing (FIG. 185) does not include the first RAM clearing processing and the second RAM clearing processing. Even if either is executed, the display data stored immediately before the supply of the operating power is stopped is stored in the first display data buffer 271 as it is, and the third display data buffer 273 is operated by the operating power. The display data stored immediately before the supply of C is stopped is stored as it is.

If an affirmative decision is made in step SC301, or if the processing of step SC304 is executed, "1" is set to the display start flag provided in the clear target area 371 of the work area 221 for specific control (step SC305). .. The display start flag is a flag for the main CPU 63 to specify whether or not display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b should be started. Is. When the value of the display start flag is "0", the main CPU 63 does not perform display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b. When the display start flag is set to "1", the main CPU 63 starts the display control of the special figure display section 37a, the special figure reservation display section 37b, the general figure display section 38a and the general figure reservation display section 38b.

As described above, the display start flag is cleared to "0" in step SC204 of the main process (FIG. 185). The processing timing is after the supply of the operating power to the main CPU 63 is started, the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, the general figure reservation display unit 38b, and the first to fourth sections. The timing is earlier than the timing at which the second timer interrupt process (FIG. 188) for executing the display control of the notification display devices 201 to 204 is first executed. Then, as described above, the display start flag is set to "1" in the display start process (FIG. 187) executed after the process at the start of supplying the operating power (step SC201 to step SC223) is completed. As a result, immediately after the supply of the operating power is resumed, the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b are maintained in the off state, and the supply of the operating power is performed. After the processing at the start (step SC201 to step SC223) is completed, the display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b is started.

Next, the second timer interrupt processing in this embodiment executed by the main CPU 63 will be described with reference to the flowchart in FIG. 188. The processes of steps SC401 to SC415 in the second timer interrupt process are executed by using the specific control program and the specific control data in the main CPU 63. In the second timer interrupt process, the interrupt is permitted when the setting confirmation process (step SC213) is started, and the interrupt is prohibited when the setting confirmation process (step SC213) is ended. In the second timer interrupt process, the interrupt is permitted when the set value update process (step SC216) is started, and the interrupt is prohibited when the set value update process (step SC216) is ended. In addition, the second interrupt process is interrupted from when the interrupt permission is set in step SC230 of the main process (FIG. 185) until the interrupt prohibition is set in step SC227 of the main process (FIG. 185). Allowed The same applies to the first timer interrupt processing (FIG. 133).

In steps SC401 to SC409, the same processing as steps S8401 to S8409 of the second timer interrupt processing (FIG. 123) in the thirty-third embodiment is executed. Then, it is determined whether the value of the type counter is "5" (step SC410). Similar to the 33rd embodiment, the type counter identifies the transmission target of the display data among the first to fifth display data buffers 271 to 275 in the main CPU 63 in the current processing time of the second timer interrupt processing. It is a counter for doing. When the value of the type counter is "1", the display data of the first display data buffer 271 is the transmission target, and when the value of the type counter is "2", the display data of the second display data buffer 272 is the transmission target. When the value of the type counter is “3”, the display data of the third display data buffer 273 is the transmission target, and when the value of the type counter is “4”, the display data of the fourth display data buffer 274 is When it becomes a transmission target and the value of the type counter is “5”, the display data of the fifth display data buffer 275 becomes a transmission target.

When the value of the type counter is any of "1" to "4", that is, any one of the special figure display portion 37a, the special figure reservation display portion 37b, the general figure display portion 38a, and the general figure reservation display portion 38b is displayed. If it is in the control situation (step SC410: NO), it is determined whether or not “1” is set in the display start flag of the work area 221 for specific control (step SC411). When the value of the type counter is "5" (step SC410: YES), or when the value of the type counter is any of "1" to "4" and the display start flag is set to "1" (Step SC410: NO, step SC411: YES), the processing of steps SC412 to SC414 is executed.

In the processing of steps SC412 to SC414, first, the type data corresponding to the value of the type counter is read from the main ROM 64 (step SC412). Specifically, when the value of the type counter is "1", the type data corresponding to the first display circuit 261 is read from the main ROM 64, and when the value of the type counter is "2", the second type data is read. The type data corresponding to the display circuit 262 is read from the main ROM 64, and when the type counter value is “3”, the type data corresponding to the third display circuit 263 is read from the main ROM 64 and the type counter value is When it is "4", the type data corresponding to the fourth display circuit 264 is read from the main ROM 64, and when the type counter value is "5", the type data corresponding to the fifth display circuit 265 is mainly read. Read from the side ROM 64.

Then, the display data is read from the display data buffers 271-275 corresponding to the value of the type counter (step SC413). Specifically, when the value of the type counter is "1", the display data is read from the first display data buffer 271, and when the value of the type counter is "2", the second display data buffer 272 is read. When the display data is read and the value of the type counter is “3”, the display data is read from the third display data buffer 273, and when the value of the type counter is “4”, the fourth display data buffer 274 is read. The display data is read, and when the value of the type counter is "5", the display data is read from the fifth display data buffer 275.

After that, the transmission processing of various signals is executed (step SC414). In the transmission processing, signals are output to the type data signal line LN1 and the type clock signal line LN2 so that the type data read in step SC412 is transmitted to the display IC 266. In the transmission process, signals are output to the display data signal line LN3 and the display clock signal line LN4 so that the display data read in step SC413 is transmitted to the display IC 266.

On the other hand, when the value of the type counter is any of "1" to "4" and the display start flag is not set to "1" (step SC410 and step SC411: NO), the processing of steps SC412 to SC414 Do not run. As a result, even if the supply of the operating power to the main CPU 63 is started, the special figure display portion 37a, the special figure reservation display portion 37b, and the general figure display portion 38a are set until the display start flag is set to "1". The display control of the special figure reservation display section 38b is not started, and the special figure display section 37a, the special figure reservation display section 37b, the general figure display section 38a, and the general figure reservation display section 38b are maintained in the off state.

If a negative determination is made in step SC411, or if the process of step SC414 is executed, interrupt permission is set to permit the generation of the first timer interrupt process and the second timer interrupt process (step SC415).

Next, the display contents of the special figure display unit 37a and the general figure display unit 38a corresponding to the situation at the time of starting the supply of the operating power will be described. FIG. 189 is an explanatory diagram for explaining the display contents of the special figure display unit 37a and the general figure display unit 38a corresponding to the situation when the supply of operating power is started.

Since "1" is not yet set in the initial display completed flag 373 at the factory shipping stage, the supply of operating power to the main CPU 63 is started and the displays of the special figure display portion 37a and the general figure display portion 38a are displayed. When started, initial display is started on the special figure display portion 37a and the general figure display portion 38a. The initial display on the special figure display portion 37a is a pattern on the special figure display portion 37a when the entry of the game ball into the first operation opening 33 or the second operation opening 34 occurs and the start condition of the game time is satisfied. It continues until the variable display of is started. The initial display on the universal figure display portion 38a is continued until a game ball enters the through gate 35 and the variable display of the pattern on the universal figure display portion 38a is started.

If it is not at the factory shipping stage, that is, if the initial display completion flag 373 has already been set to "1", the first RAM clearing process is performed in the process (step SC201 to step SC223) at the start of supplying the operating power. The supply of operating power is stopped regardless of whether it is executed, the setting value update process is executed, the setting confirmation process is executed, or these processes are not executed. The special figure display section 37a and the general figure display section 38a are display-controlled so that the display contents immediately before are displayed. As a result, even if the special figure display unit 37a and the general figure display unit 38a are checked, it is possible to prevent the setting value update processing (step SC216) from being specified.

Particularly, the display contents when the display of the special figure display unit 37a and the general figure display unit 38a are started, and the display contents of the special figure display unit 37a and the general figure display unit 38a immediately before the supply of the operating power is stopped are displayed. Are the same. Thus, after confirming and memorizing the display contents of the special figure display unit 37a and the general figure display unit 38a immediately before the supply of the operating power is stopped, the special figure display unit 37a and the general figure are displayed after the start of the supply of the operating power. Even if the display content initially displayed on the display unit 38a is confirmed, it is possible to prevent the setting value update process (step SC216) from being specified.

Further, by setting the first display data buffer 271 and the third display data buffer 273 in the non-clear target area 372 which is not the target of execution of the first RAM clear processing and the second RAM clear processing in the work area 221 for specific control, The display content when the display of the special figure display unit 37a and the general figure display unit 38a is the same as the display content of the special figure display unit 37a and the general figure display unit 38a immediately before the supply of the operating power is stopped. This is the configuration. In other words, even if the special figure display unit 37a and the general figure display unit 38a are checked, no special process is required to make it impossible to specify whether or not the setting value update process (step SC216) has been executed. .. Therefore, it is possible to achieve the excellent effects as already described while suppressing an increase in processing load.

The area not to be cleared 372 is not limited to the configuration in which both the first display data buffer 271 and the third display data buffer 273 are provided, and the first display data buffer 271 is not to be cleared. Although provided, the third display data buffer 273 may be provided in the clear target area 371. In this case, when the first RAM clearing process or the second RAM clearing process is executed when the supply of the operating power is started, the special figure display unit 37a displays the contents displayed before the supply of the operating power is stopped. However, the initial display is performed on the universal figure display section 38a. Alternatively, the third display data buffer 273 is provided in the non-clearing target area 372, but the first display data buffer 271 may be provided in the clearing target area 371. In this case, when the first RAM clearing process or the second RAM clearing process is executed when the supply of the operating power is started, the general display unit 38a displays the contents displayed before the supply of the operating power is stopped. However, the initial display is performed on the special figure display portion 37a.

Further, in a configuration in which a round display unit for notifying the number of round games that occur in the opening/closing execution mode triggered by the jackpot result is provided as a display unit whose display is controlled by the main CPU 63. May be configured such that an area for storing display data for displaying on the round display unit is provided in the non-clearing target area 372. In this case, the first RAM clearing process or the second RAM clearing process is executed when the supply of the operating power is started when the supply of the operating power is stopped while the predetermined display is being performed on the round display unit. Even in this case, the predetermined display is restarted on the round display unit.

In addition, all the display units including the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b which are directly display-controlled by the main CPU 63 perform display. The area in which the display data is stored may not be initialized by the first RAM clearing process and the second RAM clearing process. In this case, the display unit directly controlled by the main CPU 63 supplies the operating power even if the first RAM clearing process or the second RAM clearing process is executed when the supply of the operating power is started. The display according to the display contents before the stop is performed. In the configuration, although the display according to the display contents before the supply of the operating power is stopped is temporarily started on the special figure reservation display unit 37b and the general figure reservation display unit 38b, the corresponding reservation information is 0 after that. It may be configured to switch to the display content corresponding to the individual number.

The area in which the display data for displaying on the special figure reservation display section 37b and the general figure reservation display section 38b is stored is initialized when the first RAM clear processing or the second RAM clear processing is executed. However, it may be configured such that the special figure hold display section 37b and the general figure hold display section 38b are displayed in such a manner that the number of corresponding hold information is difficult for the player to understand. In this case, by performing the first RAM clearing process or the second RAM clearing process, a display indicating that the corresponding pending information is 0 is displayed on each of the special figure pending display section 37b and the general figure pending display section 38b. Even if it is broken, it is difficult for the player to understand that the display indicating that the number of pieces of the hold information is 0 is displayed. However, it becomes difficult to specify that the first RAM clearing process or the second RAM clearing process has been executed.

<56th Embodiment>
In this embodiment, the display contents of the special figure display portion 37a and the general figure display portion 38a when the supply of the operating power to the main CPU 63 is restarted are different from those in the 55th embodiment. The structure different from that of the 55th embodiment will be described below. The description of the same configuration as the 55th embodiment is basically omitted.

FIG. 190 is an explanatory diagram for explaining each area provided in the clear target area 371 of the work area 221 for specific control.

In the clear target area 371, a second display data buffer 272 in which display data for causing the special figure reservation display section 37b to perform a predetermined display is stored, and for causing the general figure reservation display section 38b to perform a predetermined display Not only the fourth display data buffer 274 in which display data is stored and the fifth display data buffer 275 in which display data for causing the first to fourth notification display devices 201 to 204 to perform a predetermined display are stored A first display data buffer 271 in which display data for causing the special figure display unit 37a to perform a predetermined display is stored; and a first display data buffer 271 in which display data for causing the normal figure display unit 38a to perform a predetermined display is stored. A 3 display data buffer 273 is provided. Therefore, when the first RAM clear process (step SC218) is executed in the main process (FIG. 185) or the second RAM clear process of the set value update process (step SC216) is executed, the operating power is supplied. The display data corresponding to the display contents of the special figure display portion 37a and the general figure display portion 38a immediately before the stop will be erased.

In the clear target area 371, an initial display flag 375 is provided in addition to the first to fifth display data buffers 271 to 275. The initial display flag 375 is a flag for the main CPU 63 to specify whether or not there is a situation in which the initial display needs to be performed on the special figure display portion 37a and the general figure display portion 38a. Since the initial display flag 375 is provided in the clear target area 371, when the first RAM clear process or the second RAM clear process is executed in the main process (FIG. 185), the initial display flag 375 is set to "0". It will be cleared. Therefore, when the first RAM clearing process or the second RAM clearing process is executed in the main process (FIG. 185), the special figure display is performed after the process (step SC201 to step SC223) at the start of supplying the operating power is executed. When the display of the section 37a and the general figure display section 38a is started, the initial display is performed on the special figure display section 37a and the general figure display section 38a.

FIG. 191 is a flowchart showing the display start processing in this embodiment executed by the main CPU 63. Note that the processing of step SC501 to step SC511 in the display start processing is executed by using the specific control program and the specific control data in the main CPU 63.

When "1" is not set in the initial display flag 375 (step SC501: NO), the initial display data for special drawing is set in the first display data buffer 271 (step SC502) and the initial for general drawing is set. The display data is set in the third display data buffer 273 (step SC503). Then, "1" is set to the initial display flag 375 (step SC504).

By performing display control of the special figure display unit 37a using the initial display data for special figure stored in the first display data buffer 271, the initial display is performed on the special figure display unit 37a. The display content of the initial display on the special figure display part 37a is arbitrary, but for example, all of the plurality of light emitting parts provided in the special figure display part 37a may be in a light emitting state, and the display may be provided on the special figure display part 37a. A configuration may be adopted in which a part of the plurality of light emitting units thus formed are in a light emitting state. When some of the light emitting units are in the light emitting state, the light emitting units that are in the light emitting state and the light emitting units that are maintained in the off state may be alternately arranged in the arrangement order. Further, the display content of the initial display on the special figure display portion 37a is different from the display content stopped and displayed for notifying the game result of the game times on the special figure display portion 37a. The display content of the initial display on the special figure display unit 37a is different from the display content displayed in the situation where the variable display of the picture is being performed on the special figure display unit 37a. This makes it possible to clearly specify that the initial display is being performed on the special figure display unit 37a.

By performing display control of the general figure display unit 38a using the initial display data for general figure stored in the third display data buffer 273, initial display is performed on the general figure display unit 38a. The display content of the initial display on the public figure display unit 38a is arbitrary, but, for example, all of the plurality of light emitting units provided on the public figure display unit 38a may be in a light emitting state, and the general figure display unit 38a may be provided. A configuration may be adopted in which a part of the plurality of light emitting units thus formed are in a light emitting state. When some of the light emitting units are in the light emitting state, the light emitting units that are in the light emitting state and the light emitting units that are maintained in the off state may be alternately arranged in the arrangement order. Further, the display content of the initial display on the public figure display unit 38a is different from the display content that is stopped and displayed to notify the result of the vibration release lottery in the variable display times on the public figure display unit 38a. There is. The display content of the initial display on the public figure display unit 38a is different from the display content displayed in the situation where the variable display of the picture is being performed on the public figure display unit 38a. As a result, it is possible to clearly specify that the initial display is being performed on the public figure display unit 38a.

If an affirmative decision is made in step SC501, by referring to the storage area in which information indicating whether or not the game time is being executed in the clear target area 371 of the work area 221 for specific control is stored, It is determined whether or not it is in a situation where the supply of the operating power is resumed after the supply of the operating power is stopped during execution of (step SC505). Information indicating that the game time is being executed is stored in the storage area when the game time is started, and information indicating that the game time is being executed is stored when the game time is ended. Erased from the area. The information in the storage area is stored and retained when the backup power is supplied to the work area 221 for specific control even if the supply of the operating power to the main CPU 63 is stopped, and the operation to the main CPU 63 is performed. It is also stored and held when the first RAM clearing process and the second RAM clearing process are not executed when the power supply is restarted.

In addition, by referring to the storage area in the clear target area 371 of the work area 221 for specific control that stores information indicating whether the open/close execution mode is being executed, the operating power during the open/close execution mode is being executed. It is determined whether or not the supply of operating power has been restarted after the supply of power has been stopped (step SC506). The storage area stores information indicating that the opening/closing execution mode is being executed when the opening/closing execution mode is started, and indicates that the opening/closing execution mode is being executed when the opening/closing execution mode is ended. The information is erased from the storage area. The information in the storage area is stored and retained when the backup power is supplied to the work area 221 for specific control even if the supply of the operating power to the main CPU 63 is stopped, and the operation to the main CPU 63 is performed. It is also stored and held when the first RAM clearing process and the second RAM clearing process are not executed when the power supply is restarted.

If the last time the supply of operating power was stopped was neither during the game times nor during the opening/closing execution mode (step SC505 and step SC506: NO), the initial display data for special maps is the first display data. The data is set in the buffer 271 (step SC507). By performing the display control of the special figure display unit 37a using the initial display data for special figure stored in the first display data buffer 271, the initial display already described in the special figure display unit 37a is performed. On the other hand, if the last time the supply of operating power was stopped was during the game time or during the open/close execution mode (step SC505 or step SC506: YES), the initial display data for special maps is Since it is not set in the 1 display data buffer 271, the display data stored before the supply of the operating power is stopped remains in the first display data buffer 271. Therefore, when the display on the special figure display unit 37a is started, the display content of the special figure display unit 37a immediately before the supply of the operating power is stopped is restarted as it is.

When the affirmative judgment is made in step SC505, the affirmative judgment is made in step SC506, or the process of step SC507 is executed, the change of the general figure display portion 38a in the clear target area 371 of the work area 221 for specific control is performed. By referring to the storage area in which the information indicating whether or not it is being displayed is stored, the supply of the operating power is resumed after the supply of the operating power is stopped during the variable display of the pattern on the normal figure display portion 38a. It is determined whether or not the situation is that (step SC508). The storage area stores information indicating that the variable display of the picture is being performed on the universal figure display section 38a when the variable display of the pattern is started on the universal figure display section 38a. When the variable display of the pattern is terminated at, the information indicating that the variable display of the pattern is being executed is erased from the storage area on the public figure display portion 38a. The information in the storage area is stored and retained when the backup power is supplied to the work area 221 for specific control even if the supply of the operating power to the main CPU 63 is stopped, and the operation to the main CPU 63 is performed. It is also stored and held when the first RAM clearing process and the second RAM clearing process are not executed when the power supply is restarted.

Further, by referring to the storage area in the clear target area 371 of the work area 221 for specific control that stores information indicating whether or not the normal power open state is being executed, the normal power open state is being executed. It is determined whether or not the supply of the operating power is resumed after the supply of the operating power is stopped (step SC509). Information indicating that the universal power open state is being executed is stored in the storage area when the universal power open state is started, and the universal power open state is being executed when the universal power open state is ended. The information indicating that there is is erased from the storage area. The information in the storage area is stored and retained when the backup power is supplied to the work area 221 for specific control even if the supply of the operating power to the main CPU 63 is stopped, and the operation to the main CPU 63 is performed. It is also stored and held when the first RAM clearing process and the second RAM clearing process are not executed when the power supply is restarted.

If the last time the supply of operating power was stopped was neither during the variable display of the picture on the universal figure display section 38a nor during the open state of the regular electricity (step SC508 and step SC509: NO), for the regular figure The initial display data of is set in the third display data buffer 273 (step SC510). By performing display control of the general figure display unit 38a using the initial display data for general figure stored in the third display data buffer 273, the initial display already described in the general figure display unit 38a is performed. On the other hand, when the last stop of the supply of the operating power was either the execution of the variable display of the pattern on the universal graphic display unit 38a or the execution of the universal power open state (step SC508 or step SC509: YES), Since the initial display data for general use is not set in the third display data buffer 273, the display data stored before the supply of the operating power is stored in the third display data buffer 273 as it is. .. Therefore, when the display on the public figure display unit 38a is started, the display content of the public figure display unit 38a immediately before the supply of the operating power is stopped is restarted as it is.

When the process of step SC504 is executed, the affirmative judgment is made in step SC508, the affirmative judgment is made in step SC509, or the process of step SC510 is executed, the clear target area of the work area 221 for specific control is executed. "1" is set to the display start flag provided in 371 (step SC511). The display start flag mainly determines whether or not the display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure reservation display unit 38a, and the general figure reservation display unit 38b should be started, as in the case of the 55th embodiment. This is a flag for specifying by the side CPU 63. When the value of the display start flag is "0", the main CPU 63 does not perform display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b. When the display start flag is set to "1", the main CPU 63 starts the display control of the special figure display section 37a, the special figure reservation display section 37b, the general figure display section 38a and the general figure reservation display section 38b.

Similar to the 55th embodiment, the display start flag is cleared to "0" in step SC204 of the main process (FIG. 185). The processing timing is after the supply of the operating power to the main CPU 63 is started, the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, the general figure reservation display unit 38b, and the first to fourth sections. The timing is earlier than the timing at which the second timer interrupt process (FIG. 188) for executing the display control of the notification display devices 201 to 204 is first executed. Then, in the display start processing (FIG. 191) executed after the processing at the start of supplying the operating power (step SC201 to step SC223) is completed, the display start flag is set to “1”. As a result, immediately after the supply of the operating power is resumed, the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b are maintained in the off state, and the supply of the operating power is performed. After the processing at the start (step SC201 to step SC223) is completed, the display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b is started.

In particular, in the display start process (FIG. 191), even if both the first RAM clear process and the second RAM clear process are not executed in the main process (FIG. 185) as already described, the first display data buffer 271 stores The initial display data for special figures may be set and the initial display data for general figures may be set in the third display data buffer 273. In this case, if the display control of the special figure display unit 37a and the general figure display unit 38a is started immediately after the supply of the operating power to the main CPU 63 is started, the special figure display unit 37a and the general figure display unit are displayed. In 38a, the initial display will be started immediately after the display content immediately before the supply of the operating power is stopped is displayed. Then, the player visually observing such a change in the display contents starts the initial display on the special figure display portion 37a and the general figure display portion 38a in a situation where both the first RAM clear processing and the second RAM clear processing are not executed. You will be able to understand what was done. On the other hand, when the display data is set in the first display data buffer 271 and the third display data buffer 273 in the display start process (FIG. 191), the display start flag is set after the process of setting the display data ends. Is set to "1" and display of the special figure display portion 37a and the general figure display portion 38a is started. This makes it possible to prevent the display contents from changing as described above.

Next, the display contents of the special figure display unit 37a and the general figure display unit 38a corresponding to the situation at the time of starting the supply of the operating power will be described. FIG. 192 is an explanatory diagram for explaining the display contents of the special figure display unit 37a and the general figure display unit 38a corresponding to the situation when the supply of the operating power is started.

When the first RAM clear process is executed in the process (step SC201 to step SC223) at the start of supplying the operating power or the second RAM clear process of the set value update process is executed, the initial display flag 375 is set to "1." When the display of the special figure display part 37a and the general figure display part 38a is started because the supply of the operating power to the main CPU 63 is started, the special figure display part 37a and the general figure display are displayed. Initial display is started in the section 38a. The initial display on the special figure display portion 37a is a pattern on the special figure display portion 37a when the entry of the game ball into the first operation opening 33 or the second operation opening 34 occurs and the start condition of the game time is satisfied. It continues until the variable display of is started. The initial display on the universal figure display portion 38a is continued until a game ball enters the through gate 35 and the variable display of the pattern on the universal figure display portion 38a is started. Even at the factory shipping stage, since "1" is not set in the initial display flag 375, the initial display is started on the special figure display portion 37a and the general figure display portion 38a.

Whether the first RAM clearing process is executed based on the “RAM clearing operation” as described above or the second RAM clearing process of the set value updating process is executed based on the “setting change operation”, When the special figure display unit 37a and the general figure display unit 38a are displayed, initial display is performed on the special figure display unit 37a and the general figure display unit 38a, so that supply of operating power is started. Whether the first RAM clearing process or the set value updating process is executed even if the display contents of the display units 37a and 38a when the display is started on the diagram display unit 37a and the general figure display unit 38a are confirmed. I can't figure it out. As a result, even if the display contents of the special figure display unit 37a and the general figure display unit 38a when the supply of the operating power is started can be confirmed, it cannot be specified whether or not the set value updating process has been executed. It becomes possible to do.

Even if the first RAM clearing process and the second RAM clearing process of the set value updating process are not executed in the process (step SC201 to step SC223) at the time of starting the supply of the operating power, the situation where the supply of the operating power is stopped is a game. If the special figure display unit 37a starts the display when the current state is neither the current execution time nor the open/close execution mode, the initial display is started on the special figure display unit 37a. Even if the first RAM clearing process and the second RAM clearing process of the set value updating process are not executed in the process at the start of supplying the operating power (step SC201 to step SC223), the supply of the operating power is stopped. When the display is started on the public figure display unit 38a in the case where the display is not being executed on the general figure display unit 38a while the variable display of the pattern is being executed or the general electric open state is being executed. Initial display is started in the section 38a. Then, as described above, even when the first RAM clearing process or the second RAM clearing process of the set value updating process is executed in the process (step SC201 to step SC223) at the time of starting the supply of the operating power, the special figure display unit 37a and Initial display is carried out on the universal figure display section 38a. Accordingly, even if it is confirmed that the initial display is performed on the special figure display unit 37a and the general figure display unit 38a when the supply of the operating power is started, the first RAM clear processing and the second RAM clear processing are performed. It becomes possible not to specify that any one has been executed.

On the other hand, the situation in which the supply of operating power is stopped is either during execution of the game times or during execution of the opening/closing execution mode, and the first RAM in the process (step SC201 to step SC223) at the time of starting the supply of operating power. If the clearing process and the second RAM clearing process are not executed, when the display is started on the special figure display unit 37a, the special figure display unit has the display content just before the supply of the operating power is stopped. The display of 37a is controlled. In addition, when the supply of the operating power is stopped is either the execution of the variable display of the picture on the universal display unit 38a or the execution of the universal power open state, the process at the start of the supply of the operating power (step SC201). ~ If the first RAM clearing process and the second RAM clearing process are not executed in step SC223), the display content immediately before the supply of the operating power is stopped when the display is started on the universal figure display unit 38a The general figure display unit 38a is display-controlled so that As a result, when the game situation immediately before the supply of the operation power is stopped is resumed when the supply of the operation power is resumed, the special figure display unit 37a and the normal state are displayed in a mode corresponding to the restart of the game situation. It becomes possible to start the display on the diagram display unit 38a.

It should be noted that the contents of the initial display displayed on the special figure display portion 37a are different when the first RAM clearing process is executed and when the second RAM clearing process is executed when the supply of the operating power is started. It may be configured to have. Further, the contents of the initial display displayed on the universal figure display unit 38a are different when the first RAM clearing process is executed and when the second RAM clearing process is executed when the supply of the operating power is started. It may be configured to have.

Further, when the first RAM clearing process or the second RAM clearing process is executed when the supply of the operating power is started, the initial display is performed on the special figure display part 37a, whereas the general figure display part 38a is displayed. Then, the display content before the supply of the operating power is stopped may be displayed. Further, when the first RAM clearing process or the second RAM clearing process is executed when the supply of the operating power is started, the special figure display section 37a displays the initial display on the public figure display section 38a. Then, the display content before the supply of the operating power is stopped may be displayed.

Further, there are a plurality of types of initial display on the special figure display unit 37a, and when initial supply is performed on the special figure display unit 37a when the supply of operating power is started, the initial display is selected by lottery. The initial display may be performed on the special figure display unit 37a. In addition, there are a plurality of types of initial display on the general figure display unit 38a, and when the initial display is performed on the general figure display unit 38a when the supply of operating power is started, it is selected by lottery. The initial display may be performed on the public figure display unit 38a.

Further, in a configuration in which a round display unit for notifying the number of round games that occur in the opening/closing execution mode triggered by the jackpot result is provided as a display unit whose display is controlled by the main CPU 63. Indicates that either the first RAM clear processing or the second RAM clear processing has been executed when the supply of the operating power has been started, or both the first RAM clear processing and the second RAM clear processing have not been executed. Even if there is, the initial display may be performed on the round display unit. As a result, even if the round display section is confirmed, it is not possible to specify whether the first RAM clear processing or the second RAM clear processing has been executed.

In addition, all the display units, including the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b, which are directly display-controlled by the main CPU 63, supply the operating power. When either the first RAM clearing process or the second RAM clearing process is executed or the first RAM clearing process or the second RAM clearing process is not executed, the initial display is displayed. It may be configured to be performed. In the configuration, although the initial display is temporarily started on the special figure reservation display section 37b and the general figure reservation display section 38b, the display content corresponding to the fact that the corresponding reservation information is 0 is switched thereafter. It may be configured.

Further, when the first RAM clearing process is executed when the supply of the operating power is started, steps SC502 to SC503 of the display starting process (FIG. 191) are executed, while the second RAM clearing process is executed. In this case, the display start process (FIG. 191) may be configured such that steps SC502 to SC503 are not executed. If the second RAM clearing process is executed when the supply of the operating power is started, steps SC502 to SC503 of the display starting process (FIG. 191) are executed, while the first RAM clearing process is executed. In this case, the display start process (FIG. 191) may be configured such that steps SC502 to SC503 are not executed.

<57th Embodiment>
In the present embodiment, the contents displayed on the special figure display portion 37a and the general figure display portion 38a when the supply of operating power to the main CPU 63 is restarted are different from those in the 56th embodiment. The configuration different from that of the 56th embodiment will be described below. The description of the same configuration as the 56th embodiment is basically omitted.

FIG. 193 is a flowchart showing the display start processing in this embodiment executed by the main CPU 63. Note that the processing of step SC601 to step SC605 in the display start processing is executed using the program for specific control and the data for specific control in the main CPU 63. Further, the clear target area 371 in the specific control work area 221 is provided with first to fifth display data buffers 271 to 275 and an initial display flag 375.

If "1" is not set in the initial display flag 375 (step SC601: NO), the special display deviation display data is set in the first display data buffer 271 (step SC602), and the general drawing deviation is performed. The display data is set in the third display data buffer 273 (step SC603). Then, "1" is set to the initial display flag 375 (step SC604).

The deviation display data for the special figure is selected by the stop result setting processing (step S509) for the deviation result when the result of the success/failure determination processing (step S504) of the special figure fluctuation start processing (FIG. 13) is the deviation result. This is the display data that is displayed. In other words, the special figure deviation display data is display data for finally causing the special figure display unit 37a to perform the deviation display in the game game in which the result of the hit determination processing is the deviation result. Since only one type of deviation display data for special figures is set, there is also one kind of deviation display in the special figure display portion 37a. In addition, a plurality of types of hit displays that are finally displayed on the special figure display portion 37a in the game times in which the result of the hit/miss determination processing is a hit result are set, but the deviation display is different from these multiple types of hit displays It is displayed.

By performing the display control of the special figure display unit 37a by using the special figure deviation display data stored in the first display data buffer 271, the special figure display unit 37a performs the deviation display. Although the display content of the off display is arbitrary, for example, only one light emitting unit of the plurality of light emitting units provided in the special figure display unit 37a may be in a light emitting state, and the plurality of light emitting units emit light. It may be configured to be in a state.

The disengagement display data for the universal figure is executed when the result of the universal communication open lottery in the universal figure universal communication control process (step S8914) of the first timer interrupt process (FIG. 133) is the disconnection result. It is the display data for finally causing the general figure display unit 38a to display the deviation in the variable display times of the general figure display unit 38a corresponding to. Since only one type of deviation display data for a general figure is set, there is also one kind of deviation display on the general figure display unit 38a. In addition, only one type of hit display finally set on the public figure display section 38a is set in the variable display times of the public figure display section 38a in which the result of the general electric open lottery is the winning result, but the deviation display is The display content is different from the hit display.

By performing the display control of the general figure display unit 38a by using the general figure deviation display data stored in the third display data buffer 273, the general figure display unit 38a performs the misalignment display. Although the display content of the off-display is arbitrary, for example, only one light emitting unit of the plurality of light emitting units provided in the general-purpose display unit 38a may be in a light emitting state, and the plurality of light emitting units emit light. It may be configured to be in a state.

If an affirmative decision is made in step SC601, or if the processing of step SC604 is executed, "1" is set to the display start flag provided in the clear target area 371 of the work area 221 for specific control (step SC605). .. The display start flag mainly determines whether or not the display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure reservation display unit 38a, and the general figure reservation display unit 38b should be started, as in the case of the 55th embodiment. This is a flag for specifying by the side CPU 63. When the value of the display start flag is "0", the main CPU 63 does not perform display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b. When the display start flag is set to "1", the main CPU 63 starts the display control of the special figure display section 37a, the special figure reservation display section 37b, the general figure display section 38a and the general figure reservation display section 38b.

Similar to the 55th embodiment, the display start flag is cleared to "0" in step SC204 of the main process (FIG. 185). The processing timing is after the supply of the operating power to the main CPU 63 is started, the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, the general figure reservation display unit 38b, and the first to fourth sections. The timing is earlier than the timing at which the second timer interrupt process (FIG. 188) for executing the display control of the notification display devices 201 to 204 is first executed. Then, the display start flag (1) is set in the display start process (FIG. 193) executed after the process (step SC201 to step SC223) at the start of supplying the operating power is completed. As a result, immediately after the supply of the operating power is resumed, the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b are maintained in the off state, and the supply of the operating power is performed. After the processing at the start (step SC201 to step SC223) is completed, the display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b is started.

In particular, in the display start process (FIG. 193), when either the first RAM clear process or the second RAM clear process is executed in the main process (FIG. 185) as already described, the special display in the first display data buffer 271 is performed. The deviation display data for general purpose is set in the third display data buffer 273 while the deviation display data for general purpose is set. In this case, if the display control of the special figure display unit 37a and the general figure display unit 38a is started immediately after the supply of the operating power to the main CPU 63 is started, the special figure display unit 37a and the general figure display unit are displayed. At 38a, the off-display is started immediately after the display content immediately before the supply of the operating power is stopped is displayed. Then, the player visually observing such a change in the display content starts the off-display on the special figure display portion 37a and the general figure display portion 38a in the situation where either the first RAM clear processing or the second RAM clear processing is executed. You will be able to understand what was done. On the other hand, when the display data is set in the first display data buffer 271 and the third display data buffer 273 in the display start process (FIG. 191), the display start flag is set after the process of setting the display data ends. Is set to "1" and display of the special figure display portion 37a and the general figure display portion 38a is started. This makes it possible to prevent the display contents from changing as described above.

On the other hand, when the initial display flag 375 is set to "1" (step SC601: YES), the processes of step SC602 and step SC603 are not executed. Therefore, the first display data buffer 271 is in a state in which the display data stored immediately before the supply of the operating power is stopped is stored as it is, and the third display data buffer 273 is immediately before the supply of the operating power is stopped. The display data stored in is stored as it is. In this case, when the display start flag is set to "1" and the display of the special figure display portion 37a is started, the display data stored in the first display data buffer 271 immediately before the supply of the operating power is stopped. Is displayed on the special figure display portion 37a. When the display start flag is set to "1" and the display of the universal figure display unit 38a is started, the display data stored in the third display data buffer 273 is displayed immediately before the supply of the operating power is stopped. Corresponding display is performed on the public figure display unit 38a.

Next, the display contents of the special figure display unit 37a and the general figure display unit 38a corresponding to the situation at the time of starting the supply of the operating power will be described. FIG. 194 is an explanatory diagram for explaining the display contents of the special figure display unit 37a and the general figure display unit 38a corresponding to the situation at the time of starting the supply of operating power.

When the first RAM clear process is executed in the process (step SC201 to step SC223) at the start of supplying the operating power or the second RAM clear process of the set value update process is executed, the initial display flag 375 is set to "1." Is not set, when the supply of operating power to the main CPU 63 is started and the display of the special figure display unit 37a and the general figure display unit 38a is started, the special figure display unit 37a and the general figure display unit 37a are displayed. The off display is started on the display unit 38a. The deviation display on the special figure display unit 37a indicates that the game ball enters the first operation opening 33 or the second operation opening 34 and the start condition of the game times is satisfied, so that the special display section 37a displays a pattern. It continues until the variable display of is started. The out-of-range display on the universal figure display section 38a is continued until the game ball enters the through gate 35 and the variable display of the pattern on the universal figure display section 38a is started. Even at the factory shipping stage, "1" is not set in the initial display flag 375, so that the special figure display portion 37a and the general figure display portion 38a start the dislocation display.

Whether the first RAM clear process is executed or the second RAM clear process of the set value update process is executed as described above, the display of the special figure display unit 37a and the general figure display unit 38a is started. When the special figure display unit 37a and the general figure display unit 38a are disengaged, the supply of operating power is started and the special figure display unit 37a and the general figure display unit 38a start the display. Even if the displayed contents of the display portions 37a and 38a are confirmed in such a case, it is not possible to grasp which of the first RAM clear process and the set value update process has been executed. As a result, even if the display contents of the special figure display unit 37a and the general figure display unit 38a when the supply of the operating power is started can be confirmed, it cannot be specified whether or not the set value updating process has been executed. It becomes possible to do.

When the first RAM clearing process and the second RAM clearing process of the set value updating process are not executed in the process (step SC201 to step SC223) at the start of supplying the operating power, the special figure display unit 37a starts displaying. In this case, the display content on the special figure display unit 37a is started with the display content immediately before the supply of the operating power is stopped, and the supply of the operating power is stopped when the display is started on the universal figure display unit 38a. The display content immediately before is started to be displayed on the universal figure display section 38a. Here, during the business hours of the game hall, the power of the pachinko machine 10 is mostly shut off in a situation where neither the game times nor the open/close execution mode are executed, and further, the general display unit 38a In most cases, the power of the pachinko machine 10 is shut off when neither the variable display time nor the normal power open state is executed. That is, the display contents of the special figure display unit 37a and the general figure display unit 38a just before the supply of the operating power is stopped are basically off-displays. Then, as described above, even when the first RAM clearing process or the second RAM clearing process of the set value updating process is executed in the process (step SC201 to step SC223) at the start of supplying the operating power, the special figure display unit 37a and The general display unit 38a displays the dislocation. Accordingly, even if it is confirmed that the special figure display portion 37a and the general figure display portion 38a are out of display when the supply of the operating power is started, the first RAM clear processing and the second RAM clear processing are performed. It becomes possible not to specify that any one has been executed.

In addition, in a configuration in which there are a plurality of types of off-displays of the special figure display unit 37a, when the first RAM clearing process or the second RAM clearing process is executed when the supply of the operating power is started, the plurality of types are displayed. It is also possible to adopt a configuration in which one kind of predetermined deviation display among the deviation displays is performed on the special figure display unit 37a. In addition, in a configuration in which there are a plurality of types of out-of-range display on the universal figure display unit 38a, when the first RAM clearing process or the second RAM clearing process is executed when the supply of operating power is started, the plurality of types are displayed. It is also possible to adopt a configuration in which one type of predetermined out-of-miss display among the out-of-display is performed on the universal figure display section 38a.

Further, when the first RAM clearing process is executed when the supply of the operating power is started, steps SC602 to SC603 of the display starting process (FIG. 193) are executed, while the second RAM clearing process is executed. In this case, the configuration may be such that steps SC602 to SC603 of the display start processing (FIG. 193) are not executed. When the second RAM clearing process is executed when the supply of the operating power is started, steps SC602 to SC603 of the display starting process (FIG. 193) are executed, while the first RAM clearing process is executed. In this case, the configuration may be such that steps SC602 to SC603 of the display start processing (FIG. 193) are not executed.

<58th Embodiment>
In this embodiment, the display contents of the special figure display portion 37a and the general figure display portion 38a when the supply of the operating power to the main CPU 63 is restarted are different from those in the 55th embodiment. The structure different from that of the 55th embodiment will be described below. The description of the same configuration as the 55th embodiment is basically omitted.

FIG. 195 is an explanatory diagram for describing each area provided in the clear target area 371 and the non-clear target area 372 of the work area 221 for specific control.

In the clear target area 371, a second display data buffer 272 in which display data for causing the special figure reservation display section 37b to perform a predetermined display is stored, and for causing the general figure reservation display section 38b to perform a predetermined display Not only the fourth display data buffer 274 in which display data is stored and the fifth display data buffer 275 in which display data for causing the first to fourth notification display devices 201 to 204 to perform a predetermined display are stored A first display data buffer 271 in which display data for causing the special figure display unit 37a to perform a predetermined display is stored; and a first display data buffer 271 in which display data for causing the normal figure display unit 38a to perform a predetermined display is stored. A 3 display data buffer 273 is provided. Therefore, when the first RAM clear process (step SC218) is executed in the main process (FIG. 185) or the second RAM clear process of the set value update process (step SC216) is executed, the operating power is supplied. The display data corresponding to the display contents of the special figure display portion 37a and the general figure display portion 38a immediately before the stop will be erased.

In the clear target area 371, an initial display flag 375 is provided in addition to the first to fifth display data buffers 271 to 275. The initial display flag 375 is a flag for the main CPU 63 to specify whether or not there is a situation in which it is necessary to perform the off display as the initial display on the special figure display unit 37a and the general figure display unit 38a. Since the initial display flag 375 is provided in the clear target area 371, when the first RAM clear process or the second RAM clear process is executed in the main process (FIG. 185), the initial display flag 375 is set to "0". It will be cleared. Therefore, when the first RAM clearing process or the second RAM clearing process is executed in the main process (FIG. 185), the special figure display is performed after the process (step SC201 to step SC223) at the start of supplying the operating power is executed. The off display is performed as the initial display on the portion 37a and the public figure display portion 38a.

The non-clearing target area 372 is provided with an initial display counter 381 for special figures and an initial display counter 382 for general figures. The special display initial display counter 381 has a plurality of types of special displays when the special display display unit 37a starts the off-display as the initial display on the special display display unit 37a. This is a counter for determining, by lottery, which kind of special display the special display is to be displayed. The numerical range that the initial display counter 381 for a special figure can take is "0 to 59", but is not limited to this and is arbitrary.

The general-purpose initial display counter 382 has a plurality of types of general-purpose figures when the general-purpose figure display section 38a displays a disengagement display as an initial display when the general-purpose figure display section 38a starts displaying. This is a counter for deciding by a lottery which kind of out-of-range display for out-of-range display should be performed. The numerical range that the initial display counter 382 for general drawings can take is "0 to 59", but the numerical range is not limited to this and is arbitrary.

The special display initial display counter 381 and the general-purpose initial display counter 382 are provided in the non-clearing target area 372 as described above. As a result, if the backup power is continuously supplied to the main RAM 65 in a situation where the supply of the operating power to the main CPU 63 is stopped, the first RAM clearing process or the first RAM clearing process or the first RAM clearing process in the main process (FIG. 185) is performed. Even if the 2RAM clear processing is executed, the initial display counter 381 for special figures and the initial display counter 382 for general figures are not initialized and the numerical information immediately before the supply of operating power is stopped is stored. Is maintained.

The numerical information of the special display initial display counter 381 and the numerical information of the general display initial display counter 382 are periodically updated by the first timer interrupt processing in the situation where the activation of the first timer interrupt processing is permitted. To be done. FIG. 196 is a flowchart showing the first timer interrupt processing in this embodiment executed by the main CPU 63. The processes of steps SC701 to SC722 in the first timer interrupt process are executed by using the program for specific control and the data for specific control in the main CPU 63.

In Step SC705 to Step SC705, the same processing as Step S8901 to Step S8905 of the first timer interrupt processing (FIG. 133) in the 35th embodiment is executed. After that, the initial display counter updating process for special figures is executed (step SC706). In the update process, the current numerical value information is read from the special display initial display counter 381, the read numerical value information is incremented by 1, and the numerical information after the addition of 1 is overwritten on the special figure initial display counter 381. To do. In this case, when the counter value exceeds the maximum value (specifically "59"), it is cleared to "0".

After that, in step SC707, it is determined whether or not "1" is set to either the game stop flag or the startup processing flag in the work area 221 for specific control. When "1" is set in any of the flags (step SC707: YES), the first timer interrupt processing is ended without executing the processing of step SC708 to step SC722. When "1" is not set in any of the flags (step SC707: NO), the initial display counter updating process for universal graphics is executed (step SC708). In the updating process, the current numerical value information is read from the general-purpose initial display counter 382, the read numerical information is incremented by 1, and the numerical information after the addition of 1 is overwritten on the general-purpose initial display counter 382. To do. In this case, when the counter value exceeds the maximum value (specifically "59"), it is cleared to "0". In Step SC709 to Step SC722, the same processing as Step S8907 to Step S8920 of the first timer interrupt processing (FIG. 133) in the 35th embodiment is executed.

Here, the special display initial display counter updating process (step SC706) is set as a process executed regardless of whether "1" is set in the game stop flag or the in-progress flag. On the other hand, the normal display initial display counter updating process (step SC708) is set as a process that is not executed when "1" is set in the game stop flag or the startup process flag. As a result, the update frequency can be made different between the special display initial display counter 381 and the general display initial display counter 382, and the special display initial display counter 381 and the general display initial display counter 382 can be changed. Can be prevented from synchronizing.

FIG. 197 is a flowchart showing the display start processing in this embodiment executed by the main CPU 63. Note that the processing of step SC801 to step SC807 in the display start processing is executed by using the specific control program and the specific control data in the main CPU 63.

If "1" is not set in the initial display flag 375 (step SC801: NO), a lottery process for out-of-drawing display data for special drawing is executed (step SC802). In the lottery process for the special figure deviation display data, the special figure deviation display lottery table 383 stored in advance in the main ROM 64 is referred to. FIG. 198(a) is an explanatory diagram for explaining the out-of-drawing display lottery table 383 for special drawings. As shown in FIG. 198(a), there are first deviation display data for special drawings, second deviation display data for special drawings, and third deviation display data for special drawings as deviation display data for special drawings. ing.

The first deviation display data for the special figure, the second deviation display data for the special figure, and the third deviation display data for the special figure have the result of the success/failure determination processing (step S504) of the special figure variation start processing (FIG. 13). This is display data that can be selected by lottery in the stop result setting process for the disengagement result (step S509) when the result is the disengagement result. That is, the first to third deviation display data for special maps are display data for finally performing the deviation display on the special drawing display portion 37a in the game game in which the result of the hit/miss determination processing is the deviation result. .. The first deviation display data for the special figure is data for displaying the first deviation display for the special figure on the special figure display portion 37a, and the second deviation display data for the special figure is the second deviation for the special figure. This is data for displaying the display on the special figure display portion 37a, and the third deviation display data for special drawing is data for displaying the third deviation display for special drawing on the special figure display portion 37a. The display contents of the first deviation display for the special drawing, the second deviation display for the special drawing, and the third deviation display for the special drawing are different from each other. Further, in the game times in which the result of the hit/miss determination processing is a hit result, a plurality of types of hit displays finally displayed on the special figure display portion 37a are set, but the first to third out-of-range displays for special figures are The display content is different from these multiple types of hit display. Even in the stop result setting process for the disconnection result (step S509), by using the initial display counter 381 for the special map and the removal display lottery table 383 for the special map, the disconnection display to be displayed on the special map display unit 37a is performed. The type is selected from the first to third out-of-range displays for special drawings.

In the special figure deviation display lottery table 383, the numerical range of the initial figure counter 381 for special figures is set for each of the first to third deviation display data for special figures. Specifically, the numerical range of the special display initial display counter 381 of “0 to 19” is set for the first special display data for special figures, and the second deviation display data for special figures is set. On the other hand, the numerical range of the special display initial display counter 381 of “20 to 39” is set, and the special display initial display counter of “40 to 59” is set for the third deviation display data for special drawing. The numerical value range of 381 is set. In other words, the selection probability of the first deviation display data for special drawings, the second deviation display data for special drawings, and the third deviation display data for special drawings in the lottery process of the deviation display data for special drawings is “1/3”. Are the same.

In the lottery process of the special display deviation display data, after reading the special figure deviation display lottery table 383, the special display initial display counter 381 provided in the clear target non-clear area 372 in the specific control work area 221. Get the current numerical information of. Then, by collating the acquired numerical information with the special display deviation display lottery table 383, the display data to be displayed this time is the first deviation display data for special drawings and the second deviation display data for special drawings. Select from the deviation display data and the third deviation display data for special drawings.

The display data selected in the lottery process for the special display deviation display data is set in the first display data buffer 271 (step SC803). By controlling the display of the special figure display unit 37a using the display data stored in the first display data buffer 271, the deviation display corresponding to the display data is performed on the special figure display unit 37a. That is, when the first deviation display data for special drawing is set in the first display data buffer 271, the first deviation display for special drawing is performed on the special drawing display portion 37a, and the first display data buffer 271 is displayed. When the second deviation display data for special drawing is set in, the second deviation display for special drawing is displayed in the special drawing display portion 37a, and the third deviation for special drawing is displayed in the first display data buffer 271. When the display data is set, the special figure display unit 37a displays the third deviation display for the special figure.

After that, the lottery process of the out-of-print display data for the universal figure is executed (step SC804). In the lottery processing for the general-purpose image non-display display data, the general-purpose non-display display lottery table 384 stored in advance in the main ROM 64 is referred to. FIG. 198(b) is an explanatory diagram for explaining the general-purpose deviation display lottery table 384. As shown in FIG. 198(b), there are the first deviation display data for general drawings, the second deviation display data for general drawings, and the third deviation display data for general drawings as the deviation display data for general drawings. ing.

The first deviation display data for public figures, the second deviation display data for general figures, and the third deviation display data for general figures are the general picture universal communication control processing (step SC716) in the first timer interrupt processing (FIG. 196). ), if the result of the ordinary electric open lottery executed by using the ordinary electric utility article opening counter C4 to determine whether or not to open the ordinary electric utility article 34a is a failure result, This is display data for causing the general figure display section 38a to finally perform the deviation display for the general figure in the variable display time of the figure display section 38a. The first deviation display data for general drawings is data for displaying the first deviation display for general drawings on the general drawing display portion 38a, and the second deviation display data for general drawings is the second deviation for general drawings. This is data for displaying the display on the public figure display unit 38a, and the third out-of-display display data for general figure is data for displaying the third off-display for general figure on the public figure display unit 38a. The display contents of the first out-of-display for the general drawing, the second out-of-display for the general drawing, and the third out-of-display for the general drawing are different from each other. In addition, a plurality of types of hit displays finally displayed on the public figure display portion 38a are set in the variable display times in which the result of the general electric open lottery is a win result. The display has different display contents from those of the multiple types of hits. In the general/university/universal electric power control process (step SC716) as well, by using the initial/universal/universal figure initial display counter 382 and the general/universal/universal figure non-display display lottery table 384, the type of non-standard display to be displayed in the general/universal figure display unit 38a is selected. Select from the first to third out-of-range displays for general drawings.

In the out-of-drawing display lottery table 384 for a general figure, the numerical range of the initial display counter 382 for a general figure is set for each of the first to third out-of-range display data for a general figure. Specifically, the numerical range of the initial display counter 382 for a general figure of "0 to 19" is set for the first deviation display data for a general figure, and is set to the second deviation display data for a general figure. On the other hand, the numerical range of the general display initial display counter 382 of "20 to 39" is set, and the general display initial display counter of "40 to 59" is set for the third deviation display data for general drawing. The numerical range of 382 is set. In other words, the selection probability of the first out-of-range display data for a general figure, the second out-of-range display data for a general figure, and the third out-of-range display data for a general figure in the lottery processing of the out-of-range display data for a general figure is "1/3. Are the same.

In the lottery processing of the out-of-drawing display data for the general figure, after reading out the out-of-drawing display lottery table 384 for the general figure, the initial display counter 382 for the general figure provided in the non-clear target area 372 in the work area 221 for the specific control. Get the current numerical information of. Then, by collating the obtained numerical information with the general-purpose out-of-drawing display lottery table 384, the display data to be displayed this time is the first out-of-place display data for general purpose and the second for general purpose display. Select from the deviation display data and the third deviation display data for general drawings.

The display data selected in the lottery process for the non-standard display data is set in the third display data buffer 273 (step SC805). By controlling the display of the public figure display unit 38a by using the display data stored in the third display data buffer 273, a deviation display corresponding to the display data is performed on the general figure display unit 38a. In other words, when the first out-of-display display data for a general figure is set in the third display data buffer 273, the first out-of-display display for a general figure is displayed on the general-drawing display section 38a, and the third display data buffer 273 is displayed. When the second deviation display data for a general figure is set in the, the second deviation display for a general figure is displayed on the general figure display unit 38a, and the third deviation for a general figure is displayed in the third display data buffer 273. When the display data is set, the third figure display for a figure is displayed on the figure display unit 38a.

After executing the processing of steps SC802 to SC805, "1" is set to the initial display flag 375 provided in the clear target area 371 in the work area 221 for specific control (step SC806).

If an affirmative decision is made in step SC801, or if the processing of step SC806 is executed, "1" is set to the display start flag provided in the clear target area 371 of the work area 221 for specific control (step SC807). .. The display start flag mainly determines whether or not the display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure reservation display unit 38a, and the general figure reservation display unit 38b should be started, as in the case of the 55th embodiment. This is a flag for specifying by the side CPU 63. When the value of the display start flag is "0", the main CPU 63 does not perform display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b. When the display start flag is set to "1", the main CPU 63 starts the display control of the special figure display section 37a, the special figure reservation display section 37b, the general figure display section 38a and the general figure reservation display section 38b.

Similar to the 55th embodiment, the display start flag is cleared to "0" in step SC204 of the main process (FIG. 185). The processing timing is after the supply of the operating power to the main CPU 63 is started, the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, the general figure reservation display unit 38b, and the first to fourth sections. The timing is earlier than the timing at which the second timer interrupt process (FIG. 188) for executing the display control of the notification display devices 201 to 204 is first executed. Then, "1" is set to the display start flag in the display start process (FIG. 197) executed after the process at the start of supplying the operating power (step SC201 to step SC223) is completed. As a result, immediately after the supply of the operating power is resumed, the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b are maintained in the off state, and the supply of the operating power is performed. After the processing at the start (step SC201 to step SC223) is completed, the display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b is started.

In particular, in the display start process (FIG. 197), as described above, when either the first RAM clear process or the second RAM clear process is executed in the main process (FIG. 185), the special display is added to the first display data buffer 271. One of the first to third outlier display data for general purpose is set, and at the same time, the third display data buffer 273 is set to any of the first to third outlier display data for general purpose. In this case, if the display control of the special figure display unit 37a and the general figure display unit 38a is started immediately after the supply of the operating power to the main CPU 63 is started, the special figure display unit 37a and the general figure display unit are displayed. At 38a, the off-display is started immediately after the display content immediately before the supply of the operating power is stopped is displayed. Then, the player visually observing such a change in the display content starts the off-display on the special figure display portion 37a and the general figure display portion 38a in the situation where either the first RAM clear processing or the second RAM clear processing is executed. You will be able to understand what was done. On the other hand, when the display data is set in the first display data buffer 271 and the third display data buffer 273 in the display start process (FIG. 197), the display start flag is set after the process of setting the display data ends. Is set to "1" and display of the special figure display portion 37a and the general figure display portion 38a is started. This makes it possible to prevent the display contents from changing as described above.

On the other hand, when "1" is set in the initial display flag 375 (step SC801: YES), the processes of steps SC802 to SC805 are not executed. Therefore, the first display data buffer 271 is in a state in which the display data stored immediately before the supply of the operating power is stopped is stored as it is, and the third display data buffer 273 is immediately before the supply of the operating power is stopped. The display data stored in is stored as it is. In this case, when the display start flag is set to "1" and the display of the special figure display portion 37a is started, the display data stored in the first display data buffer 271 immediately before the supply of the operating power is stopped. Is displayed on the special figure display portion 37a. When the display start flag is set to "1" and the display of the universal figure display unit 38a is started, the display data stored in the third display data buffer 273 is displayed immediately before the supply of the operating power is stopped. Corresponding display is performed on the public figure display unit 38a.

As described above in detail, when the first RAM clearing process is executed in the process (step SC201 to step SC223) at the start of supplying the operating power or when the second RAM clearing process of the set value updating process is executed, Since "1" is not set in the display flag 375, when the supply of operating power to the main CPU 63 is started and the display of the special figure display portion 37a and the general figure display portion 38a is started, these special characteristics are displayed. The off display is started in the figure display section 37a and the general figure display section 38a. The deviation display on the special figure display unit 37a indicates that the game ball enters the first operation opening 33 or the second operation opening 34 and the start condition of the game times is satisfied, so that the special display section 37a displays a pattern. It continues until the variable display of is started. The out-of-range display on the universal figure display section 38a is continued until the game ball enters the through gate 35 and the variable display of the pattern on the universal figure display section 38a is started. Even at the factory shipping stage, "1" is not set in the initial display flag 375, so that the special figure display portion 37a and the general figure display portion 38a start the dislocation display.

Whether the first RAM clearing process is executed or the second RAM clearing process of the set value updating process is executed as described above, the display on the special figure display unit 37a and the general figure display unit 38a is displayed. When the special figure display portion 37a and the general figure display portion 38a are disengaged when starting, supply of operating power is started and the display is performed on the special figure display portion 37a and the general figure display portion 38a. Even if the display contents of the display units 37a and 38a at the start are confirmed, it is not possible to grasp which of the first RAM clear process and the set value update process has been executed. As a result, even if the display contents of the special figure display unit 37a and the general figure display unit 38a when the supply of the operating power is started can be confirmed, it cannot be specified whether or not the set value updating process has been executed. It becomes possible to do.

When the first RAM clearing process and the second RAM clearing process of the set value updating process are not executed in the process (step SC201 to step SC223) at the start of supplying the operating power, the special figure display unit 37a starts displaying. In this case, the display content on the special figure display unit 37a is started with the display content immediately before the supply of the operating power is stopped, and the supply of the operating power is stopped when the display is started on the universal figure display unit 38a. The display content immediately before is started to be displayed on the universal figure display section 38a. Here, during the business hours of the game hall, the power of the pachinko machine 10 is mostly shut off in a situation where neither the game times nor the open/close execution mode are executed, and further, the general display unit 38a In most cases, the power of the pachinko machine 10 is shut off when neither the variable display time nor the normal power open state is executed. That is, the display contents of the special figure display unit 37a and the general figure display unit 38a just before the supply of the operating power is stopped are basically off-displays. Then, as described above, even when the first RAM clearing process or the second RAM clearing process of the set value updating process is executed in the process (step SC201 to step SC223) at the start of supplying the operating power, the special figure display unit 37a and The general display unit 38a displays the dislocation. Accordingly, even if it is confirmed that the special figure display portion 37a and the general figure display portion 38a are out of display when the supply of the operating power is started, the first RAM clear processing and the second RAM clear processing are performed. It becomes possible not to specify that any one has been executed.

In particular, when the first RAM clearing process or the second RAM clearing process of the set value updating process is executed in a configuration in which there are multiple types of out-of-range display for special drawings, a selection is made from among these multiple types of out-of-range display by lottery. The deviation display of the selected type is performed on the special figure display portion 37a. As a result, whether or not any of the first RAM clear processing and the second RAM clear processing of the set value update processing is executed from the type of the deviation display first displayed on the special figure display portion 37a when the supply of the operating power is started. It is possible to make it difficult to do so even if you try to identify.

Similarly, when the first RAM clearing process or the second RAM clearing process of the set value updating process is executed in a configuration in which there are a plurality of out-of-range displays for general drawings, a selection is made by lottery from among the plurality of out-of-place displays. The dislocation display of the selected type is performed on the public figure display unit 38a. As a result, whether or not the first RAM clearing process and the second RAM clearing process of the set value updating process are executed depending on the type of the deviation display first displayed on the universal graphic display unit 38a when the supply of the operating power is started. It is possible to make it difficult to do so even if you try to identify.

The first deviation display data for special drawing, the second deviation display data for special drawing, and the special data in the lottery processing (step SC802) for the special display deviation display data executed in the display start processing (FIG. 197). The selection probabilities of the third out-of-display data for drawing are not limited to the same configurations, and the configurations may be substantially the same although they are slightly different, or the configurations may be selection probabilities that are greatly different.

Further, the first deviation display data for the special drawing, the second deviation display data for the special drawing, and the special data in the lottery processing (step SC802) for the special display deviation display data executed in the display start processing (FIG. 197). The respective selection probabilities of the third out-of-drawing display data for figures are the first out-of-range display data for special figures, the second out-of-range display data for special figures and the third out-of-range display for special figures in the game times that result in deviation. Although the configuration is the same as the selection probability of each data, the configuration is not limited to this, and the configuration may be substantially the same although it is slightly different, or the configuration may be a selection probability that is significantly different.

Further, in the lottery process (step SC804) for the out-of-drawing display data for the universal figure, which is executed in the display start process (FIG. 197), the first out-of-range display data for the ordinary figure, the second out-of-range display data for the ordinary figure, and the ordinary-outline display data for the ordinary figure. The selection probabilities of the third outlier display data for the drawings are not limited to the same configurations, and the configurations may be slightly different but substantially the same, or the configurations may have selection probabilities that are significantly different from each other. Good.

Further, in the lottery process (step SC804) for the out-of-drawing display data for the universal figure, which is executed in the display start process (FIG. 197), the first out-of-range display data for the ordinary figure, the second out-of-range display data for the ordinary figure, and the ordinary-outline display data for the ordinary figure. The respective selection probabilities of the third outlier display data for figures are the first outlier display data for ordinary figures, the second outlier display data for ordinary figures and the third outlier for ordinary figures in the variable display times that result in outliers. Although the selection probabilities of the display data are the same as each other, the present invention is not limited to this, and the structures may be substantially the same although they are slightly different, or the selection probabilities may be greatly different.

Further, when the first RAM clearing process is executed when the supply of the operating power is started, steps SC802 to SC805 of the display starting process (FIG. 197) are executed, while the second RAM clearing process is executed. In this case, the display start process (FIG. 197) may be configured such that steps SC802 to SC805 are not executed. Further, when the second RAM clearing process is executed when the supply of the operating power is started, the steps SC802 to SC805 of the display starting process (FIG. 197) are executed, while the first RAM clearing process is executed. In this case, the display start process (FIG. 197) may be configured such that steps SC802 to SC805 are not executed.

Further, when the first RAM clearing process or the second RAM clearing process is executed when the supply of the operating power is started, the display start process (FIG. 197) is performed at step SC802, and the first to third deviations for special drawings are removed. The display data is not limited to the configuration selected by the lottery, and when the supply of the operating power is started, every time the process of step SC802 is executed, the first deviation display data for special drawing → for special drawing Second deviation display data → third deviation display data for special drawing → first deviation display data for special drawing →... The predetermined deviation display data for special drawings to be selected. The configuration may be changed in sequence.

Further, when the first RAM clearing process or the second RAM clearing process is executed when the supply of the operating power is started, in step SC804 of the display starting process (FIG. 197), the first to third deviations for general figures are omitted. The display data is not limited to the configuration selected by lottery, and when the operation power supply is started, every time the processing of step SC804 is executed, the first deviation display data for general purpose drawing → for general purpose drawing 2nd deviation display data -> 3rd deviation display data for general drawings -> 1st deviation display data for general drawings -> ... and so on. The configuration may be changed in sequence.

<59th Embodiment>
In this embodiment, the contents displayed on the special figure display portion 37a and the general figure display portion 38a when the supply of the operating power to the main CPU 63 is restarted are different from those in the 58th embodiment. Hereinafter, a configuration different from that of the 58th embodiment will be described. The description of the same configuration as the 58th embodiment is basically omitted.

FIG. 199 is a flowchart showing the display start processing in this embodiment executed by the main CPU 63. Note that the processing of step SC901 to step SC907 in the display start processing is executed using the specific control program and the specific control data in the main CPU 63.

When "1" is not set in the initial display flag 375 (step SC901: NO), a lottery process of initial display data for special drawing is executed (step SC902). In the lottery process for initial display data for special figures, the initial display lottery table 385 for special figures stored in the main ROM 64 in advance is referred to. FIG. 200A is an explanatory diagram for explaining the initial display lottery table 385 for special drawings. As shown in FIG. 200(a), as the initial display data for special maps, the first deviation display data for special drawings, the second deviation display data for special drawings, the third deviation display data for special drawings, and the special drawings There is a first hit display data for a special drawing, a second hit display data for a special drawing, and a third hit display data for a special drawing.

The first deviation display data for the special figure, the second deviation display data for the special figure, and the third deviation display data for the special figure have the result of the success/failure determination processing (step S504) of the special figure variation start processing (FIG. 13). This is display data that can be selected by lottery in the stop result setting process for the disengagement result (step S509) when the result is the disengagement result. In addition, the first hit display data for the special figure, the second hit display data for the special figure, and the third hit display data for the special figure are determined by the success/failure determination process (step S504) of the special figure variation start process (FIG. 13). This is display data that can be selected by lottery in the big hit result stop result setting process (step S507) when the result is a win result. That is, the first to third deviation display data for special maps are display data for finally performing the deviation display on the special drawing display portion 37a in the game game in which the result of the hit determination processing is the deviation result. The first to third hit display data for special maps are the display data for finally performing the hit display on the special map display portion 37a in the game game in which the result of the hit determination processing is the hit result.

The first deviation display data for the special figure is data for displaying the first deviation display for the special figure on the special figure display portion 37a, and the second deviation display data for the special figure is the second deviation for the special figure. This is data for displaying the display on the special figure display portion 37a, and the third deviation display data for special drawing is data for displaying the third deviation display for special drawing on the special figure display portion 37a. The first hit display data for special figures is data for displaying the first hit display for special figures on the special figure display portion 37a, and the second hit display data for special figures is the first hit display data for special figures. 2 is data for displaying the special hit display on the special figure display portion 37a, and the third hit display data for special drawing is data for displaying the third hit display for special drawing on the special figure display portion 37a. .. In the first hit display for the special figure, the result of the hit determination processing (step S504) of the special figure variation start processing (FIG. 13) is the hit result, and the result of the distribution determination processing (step S506) is the low certainty big hit result. It is finally displayed on the special figure display portion 37a in a certain game time. In addition, in the second winning display for special maps, the result of the hit determination processing (step S504) of the special figure fluctuation start processing (FIG. 13) is a winning result, and the result of the distribution determination processing (step S506) is low winning amount. It is finally displayed on the special figure display portion 37a in the game time which is the result of a certain jackpot. In addition, in the third hit display for special maps, the result of the hit determination processing (step S504) of the special figure fluctuation start processing (FIG. 13) is a winning result, and the result of the distribution determination processing (step S506) is the most advantageous big hit. It is finally displayed on the special figure display portion 37a in the resulting game time. The first deviation display for these special drawings, the second deviation display for special drawings, the third deviation display for special drawings, the first hit display for special drawings, the second hit display for special drawings, and the special hits The display contents of the third winning display are different from each other.

In the special display initial display lottery table 385, the special display initial display counter 381 for each of the special display first to third deviation display data and the special drawing first to third hit display data. The numerical range of is set. Specifically, the numerical range of the special display initial display counter 381 of “0 to 9” is set for the special deviation first deviation display data, and the numerical range is set to the special deviation second deviation display data. On the other hand, the numerical range of the special display initial display counter 381 of "10 to 19" is set, and the special display initial display counter of "20 to 29" is set for the third deviation display data for special drawing. The numerical range of 381 is set, and the numerical range of the initial display counter 381 for special maps of “30 to 39” is set for the first hit display data for special maps. The numerical range of the special display initial display counter 381 of "40 to 49" is set for the 2 hit display data, and the special range of "50 to 59" is set for the 3rd hit display data for the special drawing. The numerical range of the initial display counter 381 for is set. That is, the first deviation display data for special drawings, the second deviation display data for special drawings, the third deviation display data for special drawings, the first hit for special drawings in the lottery process of the initial display data for special drawings. The selection probabilities of the display data, the second hit display data for special drawing, and the third hit display data for special drawing are “1/6”, which are the same.

In the special display initial display data lottery process, after reading the special display initial display lottery table 385, the special display initial display counter 381 provided in the non-clearing target area 372 in the specific control work area 221. Get the current numerical information of. Then, by collating the acquired numerical information with the initial display lottery table 385 for special maps, the display data to be displayed this time is the first deviation display data for special maps and the second deviation data for special maps. It is selected from the deviation display data, the third deviation display data for special figures, the first hit display data for special figures, the second hit display data for special figures, and the third hit display data for special figures.

The display data selected in the lottery process of the initial display data for special figures is set in the first display data buffer 271 (step SC903). By controlling the display of the special figure display unit 37a using the display data stored in the first display data buffer 271, a deviation display or a hit display corresponding to the display data is performed on the special figure display unit 37a. .. That is, when the first deviation display data for special drawing is set in the first display data buffer 271, the first deviation display for special drawing is performed on the special drawing display portion 37a, and the first display data buffer 271 is displayed. When the second deviation display data for special drawing is set in, the second deviation display for special drawing is displayed in the special drawing display portion 37a, and the third deviation for special drawing is displayed in the first display data buffer 271. When the display data is set, the special figure display unit 37a displays the third deviation display for the special figure. Further, when the first hit display data for special drawing is set in the first display data buffer 271, the first hit display for special drawing is performed in the special drawing display portion 37a, and the first display data buffer 271 is displayed. If the second hit display data for special drawing is set in, the second hit display for special drawing is performed in the special drawing display portion 37a, and the third hit for special drawing is displayed in the first display data buffer 271. When the display data is set, the special figure display portion 37a displays the third hit for the special figure.

After that, the lottery process of the initial display data for universal graphics is executed (step SC904). In the lottery processing for initial display data for general drawings, the initial display lottery table 386 for general drawings stored in advance in the main ROM 64 is referred to. FIG. 200(b) is an explanatory diagram for explaining the initial display lottery table 386 for general figures. As shown in FIG. 200(b), as the initial display data for the general drawing, the first deviation display data for the general drawing, the second deviation display data for the general drawing, the third deviation display data for the general drawing, and the general drawing There is hit display data for use.

The first deviation display data for public figures, the second deviation display data for general figures, and the third deviation display data for general figures are the general picture universal communication control processing (step SC716) in the first timer interrupt processing (FIG. 196). ), if the result of the ordinary electric open lottery executed by using the ordinary electric utility article opening counter C4 to determine whether or not to open the ordinary electric utility article 34a is a failure result, This is display data for causing the general figure display section 38a to finally perform the deviation display for the general figure in the variable display time of the figure display section 38a. In addition, the hit display data for a general figure is finally displayed on the general figure display section 38a in the variable display times of the general figure display section 38a when the result of the above-mentioned general electric open lottery is a winning result. This is display data for displaying a hit display.

The first deviation display data for general drawings is data for displaying the first deviation display for general drawings on the general drawing display portion 38a, and the second deviation display data for general drawings is the second deviation for general drawings. This is data for displaying the display on the public figure display unit 38a, and the third out-of-display display data for general figure is data for displaying the third off-display for general figure on the public figure display unit 38a. The hit display data for a general figure is data for displaying a hit display for a general figure on the general figure display unit 38a. The display contents of the first deviating display for general drawings, the second deviating display for general drawings, the third deviating display for general drawings, and the hit display for general drawings are different from each other.

In the general-purpose initial display lottery table 386, the numerical range of the general-purpose initial display counter 382 is set for each of the first to third deviation display data for general drawings and hit display data for general drawings. Has been done. Specifically, the numerical range of the initial display counter 382 for a general figure of “0 to 14” is set for the first deviation display data for a general figure, and the numerical range of the second deviation display data for a general figure is set. On the other hand, the numerical range of the general display initial display counter 382 of "15 to 29" is set, and the general display initial display counter of "30 to 44" is set for the third deviation display data for general drawing. The numerical range of 382 is set, and the numerical range of the initial display counter 382 for general figures of “45 to 59” is set for the hit display data for general figures. That is, in the lottery process of the initial display data for general drawings, the first deviation display data for general drawings, the second deviation display data for general drawings, the third deviation display data for general drawings, and the hit display data for general drawings The selection probabilities of are 1/4 and are the same.

In the lottery process for initial display data for public figures, after reading the initial display lottery table 386 for general figures, the initial display counter 382 for general figures provided in the non-clearing target area 372 in the work area 221 for specific control. Get the current numerical information of. Then, the acquired numerical information is collated with the initial display lottery table 386 for general figures, so that the display data to be displayed this time is the first deviation display data for general figures and the second display data for general figures. Select from the deviation display data, the third deviation display data for general drawings, and the hit display data for general drawings.

The display data selected in the lottery process of the initial display data for general drawings is set in the third display data buffer 273 (step SC905). By controlling the display of the general figure display unit 38a by using the display data stored in the third display data buffer 273, a deviation display or a hit display corresponding to the display data is performed on the general figure display unit 38a. .. In other words, when the first out-of-display display data for a general figure is set in the third display data buffer 273, the first out-of-display display for a general figure is displayed on the general-drawing display section 38a, and the third display data buffer 273 is displayed. When the second deviation display data for a general figure is set in the, the second deviation display for a general figure is displayed on the general figure display unit 38a, and the third deviation for a general figure is displayed in the third display data buffer 273. When the display data is set, the third figure display for the figure is displayed on the figure display unit 38a, and when the hit display data for the figure is set in the third display data buffer 273, the figure display is displayed. A hit display for a general figure is displayed on the figure display unit 38a.

After executing the processing of steps SC902 to SC905, "1" is set to the initial display flag 375 provided in the clear target area 371 in the work area 221 for specific control (step SC906).

If an affirmative decision is made in step SC901, or if the processing of step SC906 is executed, "1" is set to the display start flag provided in the clear target area 371 of the work area 221 for specific control (step SC907). .. The display start flag mainly determines whether or not the display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure reservation display unit 38a, and the general figure reservation display unit 38b should be started, as in the case of the 55th embodiment. This is a flag for specifying by the side CPU 63. When the value of the display start flag is "0", the main CPU 63 does not perform display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b. When the display start flag is set to "1", the main CPU 63 starts the display control of the special figure display section 37a, the special figure reservation display section 37b, the general figure display section 38a and the general figure reservation display section 38b.

Similar to the 55th embodiment, the display start flag is cleared to "0" in step SC204 of the main process (FIG. 185). The processing timing is after the supply of the operating power to the main CPU 63 is started, the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, the general figure reservation display unit 38b, and the first to fourth sections. The timing is earlier than the timing at which the second timer interrupt process (FIG. 188) for executing the display control of the notification display devices 201 to 204 is first executed. Then, the display start flag (1) is set in the display start process (FIG. 199) executed after the process at the start of supplying the operating power (step SC201 to step SC223) is completed. As a result, immediately after the supply of the operating power is resumed, the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b are maintained in the off state, and the supply of the operating power is performed. After the processing at the start (step SC201 to step SC223) is completed, the display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b is started.

In particular, in the display start process (FIG. 199), as described above, when either the first RAM clear process or the second RAM clear process is executed in the main process (FIG. 185), the special display is added to the first display data buffer 271. Either one of the first to third deviation display data for special drawing and the first to third hit display data for special drawing is set, and the first to third deviation display data for general drawing and the third display data buffer 273 are set. Set one of the hit display data for general drawings. In this case, if the display control of the special figure display unit 37a and the general figure display unit 38a is started immediately after the supply of the operating power to the main CPU 63 is started, the special figure display unit 37a and the general figure display unit are displayed. In 38a, the off display or the hit display is started immediately after the display content immediately before the supply of the operating power is stopped is displayed. Then, the player visually observing such a change in the displayed contents displays the deviation or hits on the special figure display part 37a and the general figure display part 38a in the situation where either the first RAM clear process or the second RAM clear process is executed. It is possible to grasp that the display has started. On the other hand, when the display data is set in the first display data buffer 271 and the third display data buffer 273 in the display start process (FIG. 199), the display start flag is set after the process of setting the display data ends. Is set to "1" and display of the special figure display portion 37a and the general figure display portion 38a is started. This makes it possible to prevent the display contents from changing as described above.

On the other hand, when "1" is set in the initial display flag 375 (step SC901: YES), the processes of steps SC902 to SC905 are not executed. Therefore, the first display data buffer 271 is in a state in which the display data stored immediately before the supply of the operating power is stopped is stored as it is, and the third display data buffer 273 is immediately before the supply of the operating power is stopped. The display data stored in is stored as it is. In this case, when the display start flag is set to "1" and the display of the special figure display portion 37a is started, the display data stored in the first display data buffer 271 immediately before the supply of the operating power is stopped. Is displayed on the special figure display portion 37a. When the display start flag is set to "1" and the display of the universal figure display unit 38a is started, the display data stored in the third display data buffer 273 is displayed immediately before the supply of the operating power is stopped. Corresponding display is performed on the public figure display unit 38a.

Next, the display contents of the special figure display unit 37a and the general figure display unit 38a corresponding to the situation at the time of starting the supply of the operating power will be described. FIG. 201 is an explanatory diagram for explaining the display contents of the special figure display unit 37a and the general figure display unit 38a corresponding to the situation when the supply of the operating power is started.

When the first RAM clear process is executed in the process (step SC201 to step SC223) at the start of supplying the operating power or the second RAM clear process of the set value update process is executed, the initial display flag 375 is set to "1." Is not set, when the supply of operating power to the main CPU 63 is started and the display of the special figure display portion 37a and the general figure display portion 38a is started, the special figure display portion 37a and the general figure display portion 37a are displayed. The off display or the hit display is started on the display unit 38a. The deviation display or the hit display on the special view display unit 37a is performed when the game ball enters the first operation opening 33 or the second operation opening 34 and the start condition of the game time is satisfied, It continues until the variable display of the pattern is started. The deviation display or the hit display on the universal figure display portion 38a is continued until a game ball enters the through gate 35 and the variable display of the pattern on the universal figure display portion 38a is started. Even at the factory shipping stage, since "1" is not set in the initial display flag 375, the deviation display or the hit display is started on the special figure display section 37a and the general figure display section 38a.

Whether the first RAM clearing process is executed or the second RAM clearing process of the set value updating process is executed as described above, the display on the special figure display unit 37a and the general figure display unit 38a is displayed. When the special figure display section 37a and the general figure display section 38a are displayed when the start is started, the supply of operating power is started and the special figure display section 37a and the general figure display section 38a are started. Even if the display contents of these display units 37a and 38a are confirmed when the display is started, it is not possible to grasp which of the first RAM clear process and the set value update process has been executed. As a result, even if the display contents of the special figure display unit 37a and the general figure display unit 38a when the supply of the operating power is started can be confirmed, it cannot be specified whether or not the set value updating process has been executed. It becomes possible to do.

When the first RAM clearing process and the second RAM clearing process of the set value updating process are not executed in the process (step SC201 to step SC223) at the start of supplying the operating power, the special figure display unit 37a starts displaying. In this case, the display content on the special figure display unit 37a is started with the display content immediately before the supply of the operating power is stopped, and the supply of the operating power is stopped when the display is started on the universal figure display unit 38a. The display content immediately before is started to be displayed on the universal figure display section 38a. That is, when the first RAM clearing process and the second RAM clearing process of the set value updating process are not executed in the process (step SC201 to step SC223) at the start of supplying the operating power, the special figure display unit 37a and the universal figure are displayed. The display content of the display unit 38a depends on the situation at the timing when the supply of the operating power is stopped, and the display content is various. On the other hand, when the first RAM clearing process or the second RAM clearing process of the set value updating process is executed in the process (step SC201 to step SC223) at the start of supplying the operating power, the special figure display unit 37a and the normal The deviation display or the hit display is determined and displayed by lottery on the diagram display unit 38a. As a result, even when the first RAM clearing process or the second RAM clearing process of the set value updating process is executed in the process (step SC201 to step SC223) at the start of supplying the operating power, the supply of the operating power is started. In the same manner as when the first RAM clearing process and the second RAM clearing process of the set value updating process are not executed in the process (step SC201 to step SC223), the display contents of the special figure display portion 37a and the general figure display portion 38a are displayed. It is possible to diversify. Therefore, even if the display of the special figure display portion 37a and the general figure display portion 38a is started when the supply of the operating power is started and the display is confirmed, either the first RAM clear processing or the second RAM clear processing is performed. It is possible to make it difficult to identify what has been executed.

In addition, the special figure display unit 37a and the universal figure which can be selected when the first RAM clearing process or the second RAM clearing process of the set value updating process is executed in the process (step SC201 to step SC223) at the start of supplying the operating power. The display data of the display unit 38a is display data that can be selected during a normal game. As a result, the first RAM clearing process or the process at the start of supply of operating power (step SC201 to step SC223) is performed without increasing the data capacity of the display data of the special figure display unit 37a and the general figure display unit 38a. It is possible to diversify the display contents of the special figure display unit 37a and the general figure display unit 38a when the second RAM clearing process of the set value updating process is executed.

The first deviation display data for special drawings, the second deviation display data for special drawings, and the special deviation data for the special display in the lottery processing (step SC902) for initial display data for special characters executed in the display start processing (FIG. 199). Limited to the configuration in which the selection probability of each of the third deviation display data for drawing, the first hit display data for special drawing, the second hit display data for special drawing, and the third hit display data for special drawing is the same. However, the configurations may be slightly different but substantially the same, or the configurations may have significantly different selection probabilities. As a configuration having greatly different selection probabilities, for example, a configuration in which the total selection probability of the first to third outlier display data for special maps is higher than the total selection probability of the first to third per display data for special maps Or a low configuration.

Further, the first deviation display data for general drawings, the second deviation display data for general drawings, the general deviation display data for general drawings in the lottery processing (step SC904) for initial display data for general drawings executed in the display start processing (FIG. 199). The selection probabilities of the third deviation display data for drawings and the hit display data for general drawings are not limited to the same configurations, and the configurations may be slightly different but substantially the same. The configuration may be probability.

In addition, as display data selected in the lottery process (step SC902) for initial display data for special figures executed in the display start process (FIG. 199), a display not included in the result of stopping the game is performed. The display data may be included. Further, as the display data selected in the lottery process (step SC904) for the initial display data for universal figure executed in the display start process (FIG. 199), the display not included in the stop result of the variable display times is performed. The display data may be included.

If the first RAM clearing process is executed when the supply of the operating power is started, steps SC902 to SC905 of the display starting process (FIG. 199) are executed, while the second RAM clearing process is executed. In this case, the display start process (FIG. 199) may be configured such that steps SC902 to SC905 are not executed. When the second RAM clearing process is executed when the supply of the operating power is started, steps SC902 to SC905 of the display starting process (FIG. 199) are executed, while the first RAM clearing process is executed. In this case, the display start process (FIG. 199) may be configured such that steps SC902 to SC905 are not executed.

Further, when the first RAM clearing process or the second RAM clearing process is executed when the supply of the operating power is started, the first to third deviations for special drawings are made in step SC902 of the display starting process (FIG. 199). The display data and the first to third hit display data for special drawings are not limited to the configuration selected by lottery, and each time the process of step SC902 is executed when the supply of operating power is started. 1st deviation display data for special drawings → 2nd deviation display data for special drawings → 3rd deviation display data for special drawings → 1st hit display data for special drawings → 2nd hit display data for special drawings → The configuration may be such that the display data to be selected is sequentially changed in a predetermined order such as the third hit display data for special figure→the first deviation display data for special figure→.

Further, when the first RAM clearing process or the second RAM clearing process is executed when the supply of the operating power is started, the first to third deviations for general figures are removed in step SC904 of the display starting process (FIG. 199). The display data and the display data for the first to third hits for general drawings are not limited to the configuration selected by lottery, and each time the process of step SC904 is executed when the supply of the operating power is started. First deviation display data for general drawings → Second deviation display data for general drawings → Third deviation display data for general drawings → Hit display data for general drawings → First deviation display data for general drawings → ・・The display data to be selected may be sequentially changed in a predetermined order such as.

<60th Embodiment>
In the present embodiment, the display contents of the special figure display portion 37a and the general figure display portion 38a when the supply of operating power to the main CPU 63 is restarted are different from those in the 59th embodiment. Hereinafter, a configuration different from that of the 59th embodiment will be described. Note that basically the description of the same configuration as the 59th embodiment is omitted.

FIG. 202 is a flowchart showing the display start processing in this embodiment executed by the main CPU 63. Note that the processing of steps SD101 to SD115 in the display start processing is executed using the program for specific control and the data for specific control in the main CPU 63.

When "1" is not set in the initial display flag 375 (step SD101: NO), the processes of steps SD102 to SD106 are executed. The processing contents of step SD102 to step SD106 are the same as step SC901 to step SC906 of the display start processing (FIG. 199) in the 59th embodiment. As a result, when the first RAM clearing process or the second RAM clearing process of the set value updating process is executed, the display of the special figure display unit 37a and the general figure display unit 38a is started, as in the 59th embodiment. In the case of a failure, a misplacement display or a hit display is performed.

When "1" is set in the initial display flag 375 (step SD101: YES), information indicating whether or not the game game is being executed in the clear target area 371 of the specific control work area 221 is stored. By referring to the storage area, it is determined whether or not the supply of the operating power is resumed after the supply of the operating power is stopped during the execution of the game game (step SD107). Information indicating that the game time is being executed is stored in the storage area when the game time is started, and information indicating that the game time is being executed is stored when the game time is ended. Erased from the area. The information in the storage area is stored and retained when the backup power is supplied to the work area 221 for specific control even if the supply of the operating power to the main CPU 63 is stopped, and the operation to the main CPU 63 is performed. When the first RAM clearing process and the second RAM clearing process are not executed when the power supply is restarted, they are stored and held.

In addition, by referring to the storage area in the clear target area 371 of the work area 221 for specific control that stores information indicating whether or not the open/close execution mode is being executed, the operating power during the open/close execution mode is being executed. It is determined whether or not the supply of operating power has been restarted after the supply of power has been stopped (step SD108). The storage area stores information indicating that the opening/closing execution mode is being executed when the opening/closing execution mode is started, and indicates that the opening/closing execution mode is being executed when the opening/closing execution mode is ended. The information is erased from the storage area. The information in the storage area is stored and retained when the backup power is supplied to the work area 221 for specific control even if the supply of the operating power to the main CPU 63 is stopped, and the operation to the main CPU 63 is performed. When the first RAM clearing process and the second RAM clearing process are not executed when the power supply is restarted, they are stored and held.

If the last stop of the supply of operating power is neither during the game times nor during the opening/closing execution mode (step SD107 and step SD108: NO), the lottery process of the initial display data for special maps is executed. Yes (step SD109). The contents of the lottery process for initial display data for special drawings are the same as those in step SD102, and more specifically, they are the same as step SC902 in the display starting process (FIG. 199) in the 59th embodiment. As a result, as the display data for causing the special figure display unit 37a to perform the deviation display or the hit display when the display of the special figure display unit 37a is started, the first deviation display data for the special figure and the special deviation display data for the special figure are displayed. Either the second deviation display data, the third deviation display data for special maps, the first hit display data for special drawings, the second hit display data for special drawings, or the third hit display data for special drawings is selected. To be done.

The display data selected in the lottery process of the initial display data for special drawings is set in the first display data buffer 271 (step SD110). By controlling the display of the special figure display unit 37a using the display data stored in the first display data buffer 271, a deviation display or a hit display corresponding to the display data is performed on the special figure display unit 37a. .. That is, when the first deviation display data for special drawing is set in the first display data buffer 271, the first deviation display for special drawing is performed on the special drawing display portion 37a, and the first display data buffer 271 is displayed. When the second deviation display data for special drawing is set in, the second deviation display for special drawing is displayed in the special drawing display portion 37a, and the third deviation for special drawing is displayed in the first display data buffer 271. When the display data is set, the special figure display unit 37a displays the third deviation display for the special figure. Further, when the first hit display data for special drawing is set in the first display data buffer 271, the first hit display for special drawing is performed in the special drawing display portion 37a, and the first display data buffer 271 is displayed. If the second hit display data for special drawing is set in, the second hit display for special drawing is performed in the special drawing display portion 37a, and the third hit for special drawing is displayed in the first display data buffer 271. When the display data is set, the special figure display portion 37a displays the third hit for the special figure.

On the other hand, if the last time the supply of operating power was stopped was during execution of the game time or during execution of the opening/closing execution mode (step SD107 or step SD108: YES), the initial display data for special maps is Since it is not set in the 1 display data buffer 271, the display data stored before the supply of the operating power is stopped remains in the first display data buffer 271. Therefore, when the display on the special figure display unit 37a is started, the display content of the special figure display unit 37a immediately before the supply of the operating power is stopped is restarted as it is.

When the affirmative judgment is made in step SD107, the affirmative judgment is made in step SD108, or the process of step SD110 is executed, the change of the general figure display portion 38a in the clear target area 371 of the work area 221 for specific control. By referring to the storage area in which the information indicating whether or not it is being displayed is stored, the supply of the operating power is resumed after the supply of the operating power is stopped during the variable display of the pattern on the normal figure display portion 38a. It is determined whether or not it is the situation (step SD111). The storage area stores information indicating that the variable display of the picture is being performed on the universal figure display section 38a when the variable display of the pattern is started on the universal figure display section 38a. When the variable display of the pattern is terminated at, the information indicating that the variable display of the pattern is being executed is erased from the storage area on the public figure display portion 38a. The information in the storage area is stored and retained when the backup power is supplied to the work area 221 for specific control even if the supply of the operating power to the main CPU 63 is stopped, and the operation to the main CPU 63 is performed. When the first RAM clearing process and the second RAM clearing process are not executed when the power supply is restarted, they are stored and held.

In addition, by referring to the storage area in the clear target area 371 of the work area 221 for specific control that stores information indicating whether or not the normal power open state is being executed, the normal power open state is being executed. It is determined whether or not the supply of the operating power is resumed after the supply of the operating power is stopped (step SD112). Information indicating that the universal power open state is being executed is stored in the storage area when the universal power open state is started, and the universal power open state is being executed when the universal power open state is ended. The information indicating that there is is erased from the storage area. The information in the storage area is stored and retained when the backup power is supplied to the work area 221 for specific control even if the supply of the operating power to the main CPU 63 is stopped, and the operation to the main CPU 63 is performed. When the first RAM clearing process and the second RAM clearing process are not executed when the power supply is restarted, they are stored and held.

If the last time the supply of operating power was stopped was neither during execution of variable display of the picture on the universal figure display section 38a nor during execution of the universal electrical open state (step SD111 and step SD112: NO), for universal figure The initial display data lottery process is executed (step SD113). The processing contents of the lottery processing for initial display data for general drawings are the same as those in step SD104, and further, they are the same as step SC904 in the display starting processing (FIG. 199) in the above fifty-ninth embodiment. As a result, when starting the display of the general figure display unit 38a, as the display data for causing the general figure display unit 38a to perform the deviation display or the hit display, the first deviation display data for the general figure and the general deviation display data for the general figure are displayed. Any one of the second deviation display data, the third deviation display data for general drawings, and the hit display data for general drawings is selected.

The display data selected in the lottery process of the initial display data for general drawings is set in the third display data buffer 273 (step SD114). By controlling the display of the general figure display unit 38a by using the display data stored in the third display data buffer 273, a deviation display or a hit display corresponding to the display data is performed on the general figure display unit 38a. .. In other words, when the first out-of-display display data for a general figure is set in the third display data buffer 273, the first out-of-display display for a general figure is displayed on the general-drawing display section 38a, and the third display data buffer 273 is displayed. When the second deviation display data for a general figure is set in the, the second deviation display for a general figure is displayed on the general figure display unit 38a, and the third deviation for a general figure is displayed in the third display data buffer 273. When the display data is set, the third figure display for the figure is displayed on the figure display unit 38a, and when the hit display data for the figure is set in the third display data buffer 273, the figure display is displayed. A hit display for a general figure is displayed on the figure display unit 38a.

On the other hand, if the last time the supply of operating power was stopped was during execution of variable display of the picture on the universal graphic display unit 38a or during execution of the universal power open state (step SD111 or step SD112: YES), Since the initial display data for general use is not set in the third display data buffer 273, the display data stored before the supply of the operating power is stored in the third display data buffer 273 as it is. .. Therefore, when the display on the public figure display unit 38a is started, the display content of the public figure display unit 38a immediately before the supply of the operating power is stopped is restarted as it is.

When the process of step SD106 is executed, the affirmative judgment is made in step SD111, the affirmative judgment is made in step SD112, or the process of step SD114 is executed, the clear target area of the work area 221 for specific control is executed. "1" is set to the display start flag provided in 371 (step SD115). The display start flag mainly determines whether or not the display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure reservation display unit 38a, and the general figure reservation display unit 38b should be started, as in the case of the 55th embodiment. This is a flag for specifying by the side CPU 63. When the value of the display start flag is "0", the main CPU 63 does not perform display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b. When the display start flag is set to "1", the main CPU 63 starts the display control of the special figure display section 37a, the special figure reservation display section 37b, the general figure display section 38a and the general figure reservation display section 38b.

Similar to the 55th embodiment, the display start flag is cleared to "0" in step SC204 of the main process (FIG. 185). The processing timing is after the supply of the operating power to the main CPU 63 is started, the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, the general figure reservation display unit 38b, and the first to fourth sections. The timing is earlier than the timing at which the second timer interrupt process (FIG. 188) for executing the display control of the notification display devices 201 to 204 is first executed. Then, in the display start process (FIG. 202) executed after the process at the start of supplying the operating power (step SC201 to step SC223) is completed, “1” is set to the display start flag. As a result, immediately after the supply of the operating power is resumed, the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b are maintained in the off state, and the supply of the operating power is performed. After the processing at the start (step SC201 to step SC223) is completed, the display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b is started.

In particular, in the display start process (FIG. 202), as already described, even in the situation where neither the first RAM clear process nor the second RAM clear process is executed in the main process (FIG. 185), the first display data buffer 271 is stored. The initial display data for special figures may be set and the initial display data for general figures may be set in the third display data buffer 273. In this case, if the display control of the special figure display unit 37a and the general figure display unit 38a is started immediately after the supply of the operating power to the main CPU 63 is started, the special figure display unit 37a and the general figure display unit are displayed. In 38a, the initial display will be started immediately after the display content immediately before the supply of the operating power is stopped is displayed. Then, the player visually observing such a change in the display contents starts the initial display on the special figure display portion 37a and the general figure display portion 38a in a situation where both the first RAM clear processing and the second RAM clear processing are not executed. You will be able to understand what was done. On the other hand, when the display data is set in the first display data buffer 271 and the third display data buffer 273 in the display start process (FIG. 202), the display start flag is set after the process of setting the display data ends. Is set to "1" and display of the special figure display portion 37a and the general figure display portion 38a is started. This makes it possible to prevent the display contents from changing as described above.

Next, the display contents of the special figure display unit 37a and the general figure display unit 38a corresponding to the situation at the time of starting the supply of the operating power will be described. FIG. 203 is an explanatory diagram for explaining the display contents of the special figure display unit 37a and the general figure display unit 38a corresponding to the situation when the supply of the operating power is started.

When the first RAM clear process is executed in the process (step SC201 to step SC223) at the start of supplying the operating power or the second RAM clear process of the set value update process is executed, the initial display flag 375 is set to "1." Is not set, when the supply of operating power to the main CPU 63 is started and the display of the special figure display portion 37a and the general figure display portion 38a is started, the special figure display portion 37a and the general figure display portion 37a are displayed. The off display or the hit display is started on the display unit 38a. The deviation display or the hit display on the special view display unit 37a is performed when the game ball enters the first operation opening 33 or the second operation opening 34 and the start condition of the game time is satisfied, It continues until the variable display of the pattern is started. The deviation display or the hit display on the universal figure display portion 38a is continued until a game ball enters the through gate 35 and the variable display of the pattern on the universal figure display portion 38a is started. Even at the factory shipping stage, since "1" is not set in the initial display flag 375, the deviation display or the hit display is started on the special figure display section 37a and the general figure display section 38a.

Whether the first RAM clearing process is executed or the second RAM clearing process of the set value updating process is executed as described above, the display on the special figure display unit 37a and the general figure display unit 38a is displayed. When the special figure display section 37a and the general figure display section 38a are displayed when the start is started, the supply of operating power is started and the special figure display section 37a and the general figure display section 38a are started. Even if the display contents of these display units 37a and 38a are confirmed when the display is started, it is not possible to grasp which of the first RAM clear process and the set value update process has been executed. As a result, even if the display contents of the special figure display unit 37a and the general figure display unit 38a when the supply of the operating power is started can be confirmed, it cannot be specified whether or not the set value updating process has been executed. It becomes possible to do.

Even if the first RAM clearing process and the second RAM clearing process of the set value updating process are not executed in the process (step SC201 to step SC223) at the time of starting the supply of the operating power, the situation where the supply of the operating power is stopped is a game. If the special figure display section 37a starts displaying when the current time is neither during the execution of the second time nor in the open/close execution mode, the special figure display section 37a starts the deviation display or the hit display. To be done. Even if the first RAM clearing process and the second RAM clearing process of the set value updating process are not executed in the process at the start of supplying the operating power (step SC201 to step SC223), the supply of the operating power is stopped. When the display is started on the public figure display unit 38a in the case where the display is not being executed on the general figure display unit 38a while the variable display of the pattern is being executed or the general electric open state is being executed. The off display or the hit display is started in the portion 38a. Then, as described above, even when the first RAM clearing process or the second RAM clearing process of the set value updating process is executed in the process (step SC201 to step SC223) at the time of starting the supply of the operating power, the special figure display unit 37a and The general figure display unit 38a displays the deviation or the hit display. As a result, even if it is confirmed that the special figure display section 37a and the general figure display section 38a perform the off display or the hit display when the supply of the operating power is started, the first RAM clearing process and the second RAM are performed. It becomes possible to make it impossible to specify that any one of the clearing processes has been executed.

On the other hand, the situation in which the supply of operating power is stopped is either during execution of the game times or during execution of the opening/closing execution mode, and the first RAM in the process (step SC201 to step SC223) at the time of starting the supply of operating power. If the clearing process and the second RAM clearing process are not executed, when the display is started on the special figure display unit 37a, the special figure display unit has the display content just before the supply of the operating power is stopped. The display of 37a is controlled. In addition, when the supply of the operating power is stopped is either the execution of the variable display of the picture on the universal display unit 38a or the execution of the universal power open state, the process at the start of the supply of the operating power (step SC201). ~ If the first RAM clearing process and the second RAM clearing process are not executed in step SC223), the display content immediately before the supply of the operating power is stopped when the display is started on the universal figure display unit 38a The general figure display unit 38a is display-controlled so that As a result, when the game situation immediately before the supply of the operation power is stopped is resumed when the supply of the operation power is resumed, the special figure display unit 37a and the normal state are displayed in a mode corresponding to the restart of the game situation. It becomes possible to start the display on the diagram display unit 38a.

The first deviation display data for special drawing and the second deviation display for special drawing in the lottery processing (step SD102, step SD109) for initial display data for special drawing executed in the display start processing (FIG. 202). The selection probabilities of the data, the third deviation display data for the special figure, the first hit display data for the special figure, the second hit display data for the special figure, and the third hit display data for the special figure are the same. The configuration is not limited, and the configurations may be substantially the same although they are slightly different, or the configurations may have significantly different selection probabilities. As a configuration having greatly different selection probabilities, for example, a configuration in which the total selection probability of the first to third outlier display data for special maps is higher than the total selection probability of the first to third per display data for special maps Or a low configuration.

Further, the first deviation display data for a general figure and the second deviation display for a general figure in the lottery processing (step SD104, step SD113) for initial display data for a general figure executed in the display start processing (FIG. 202). The selection probabilities of the data, the third off-display data for general drawings, and the hit display data for general drawings are not limited to the same configuration, and may be slightly different but substantially the same. It may be configured such that the selection probabilities differ greatly.

Further, as the display data selected in the lottery process (step SD102, step SD109) for initial display data for special figures executed in the display start process (FIG. 202), a display not included in the result of stopping the game is displayed. It may be configured to include display data for performing the process. Further, as display data selected in the lottery process (step SD104, step SD113) for initial display data for universal figure executed in the display start process (FIG. 202), a display not included in the stop result of the variable display times. It may be configured to include display data for performing the above.

When the first RAM clear process is executed when the supply of the operating power is started, the display start process (FIG. 202) steps SD102 to SD105 are executed, while the second RAM clear process is executed. In this case, the display start process (FIG. 202) may be configured such that steps SD102 to SD105 are not executed. Further, when the second RAM clearing process is executed when the supply of the operating power is started, the steps SD102 to SD105 of the display starting process (FIG. 202) are executed, while the first RAM clearing process is executed. In this case, the display start process (FIG. 202) may be configured such that steps SD102 to SD105 are not executed.

<61st Embodiment>
In the present embodiment, the contents displayed on the special figure display portion 37a and the general figure display portion 38a when the supply of operating power to the main CPU 63 is restarted are different from those in the 56th embodiment. The configuration different from that of the 56th embodiment will be described below. The description of the same configuration as the 56th embodiment is basically omitted.

FIG. 204 is a flowchart showing the display start processing in this embodiment executed by the main CPU 63. Note that the processing of steps SD201 to SD219 in the display start processing is executed by using the specific control program and the specific control data in the main CPU 63.

If "1" is not set in the initial display flag 375 (step SD201: NO), the special drawing display portion 37a is provided in the lottery target counter provided in the clear target area 371 in the specific control work area 221. "7" corresponding to the number of the emitted light emitting units is set (step SD202). The lottery target counter is a counter for the main CPU 63 to specify whether or not it is necessary to execute the processing of steps SD203 to SD207 or the processing of steps SD211 to SD215.

After that, a random number value is acquired from the special figure random number circuit corresponding to the value of the lottery target counter (step SD203). In the present embodiment, the main control board 61 is provided with random numbers for special figures corresponding to the number of light emitting sections provided in the special figure display section 37a. Specifically, since the special figure display section 37a is provided with seven light emitting sections, seven special figure random number circuits are provided. These seven random numbers circuits for special figures have a relatively short period (for example, 1 microsecond to 7 microseconds) when the supply of the operating power to the main CPU 63 is started, and each of them is held by a different cycle. In this configuration, the backup power is supplied to stop the supply of the operating power to the main CPU 63 even when the supply of the operating power to the main CPU 63 is stopped. This is a configuration capable of storing and holding the random number value immediately before.

When the seven light emitting units of the special figure display unit 37a are the first to seventh light emitting sections and the seven special figure random number circuits are the first to seventh special figure random number circuits, the first special figure The special random number circuit corresponds to the first light emitting unit, the second special figure random number circuit corresponds to the second light emitting unit, the third special figure random number circuit corresponds to the third light emitting unit, The fourth special figure random number circuit corresponds to the fourth light emitting section, the fifth special figure random number circuit corresponds to the fifth light emitting section, and the sixth special figure random number circuit corresponds to the sixth light emitting section. The random number circuit for the seventh special figure corresponds to the seventh light emitting unit. When the value of the lottery target counter is "7", it corresponds to the first light emitting unit and the first special figure random number circuit, and when the value of the lottery target counter is "6", the second It corresponds to the light emitting unit and the second special figure random number circuit, and when the value of the lottery target counter is "5", it corresponds to the third light emitting unit and the third special figure random number circuit. When the value of the counter is “4”, it corresponds to the fourth light emitting unit and the fourth special figure random number circuit, and when the value of the lottery target counter is “3”, the fifth light emitting unit and the fourth light emitting unit. When the value of the lottery target counter is “2”, the value corresponds to the sixth light emitting unit and the sixth special figure random number circuit, and the value of the lottery target counter is When it is "1", it corresponds to the seventh light emitting unit and the seventh special figure random number circuit. Note that the random number circuits for the first to seventh special figures have the same numerical range of random numbers (for example, "0 to 255").

Then, the special drawing lighting lottery process is executed (step SD204). In the special drawing lighting lottery process, the special drawing lighting lottery table is read from the main ROM 64. In the special drawing lighting lottery table, half of the random number values that can be taken by the first to seventh special figure random number circuits are set as winning random number values. Then, the random number value acquired in step SD203 is collated with the special drawing lighting lottery table.

If the result of the special drawing lighting lottery process is a lighting win (step SD205: YES), the lighting information is displayed in the area corresponding to the current value of the lottery target counter in the clear target area 371 in the specific control work area 221. Is stored (step SD206). Each area provided corresponding to the lottery target counter is cleared to "0" when the process of step SD202 is executed.

After that, the value of the lottery target counter is decremented by 1 (step SD207), and it is determined whether the value of the lottery target counter after the decrement by 1 is "0" (step SD208). When a negative determination is made in step SD208, the processes of steps SD203 to SD207 are executed again.

When a positive determination is made in step SD208, the initial display data for special figure is set in the first display data buffer 271 (step SD209). The special display initial display data is determined by the presence or absence of lighting information corresponding to each of the lottery target counter values “1” to “7”. For example, while the lighting information corresponding to the values of the lottery target counter being “7”, “5” and “1” is stored, the lighting information corresponding to the other values of the lottery target counter is not stored. In this case, the first light emitting portion, the third light emitting portion and the seventh light emitting portion of the special figure display portion 37a are in the light emitting state, and the second light emitting portion, the fourth light emitting portion, the fifth light emitting portion and the sixth light emitting portion are Initial display data for a special figure that enables initial display for a special figure that is turned off is set in the first display data buffer 271.

By controlling the display of the special figure display unit 37a using the display data stored in the first display data buffer 271, an initial display corresponding to the display data is performed on the special figure display unit 37a. The display contents that can be displayed on the special map display unit 37a as the initial display include the display contents that can be displayed on the special map display unit 37a in the normal game, and the display contents that are not displayed on the special map display unit 37a in the normal game. Contents are also included. In addition, as the display contents that can be displayed on the special map display unit 37a as the initial display and that can be displayed on the special map display unit 37a in the normal game, the final contents are displayed on the special map display unit 37a in the game result of the deviation result. Included is a special display deviation display and a special result hit display that is finally displayed on the special figure display portion 37a in the game result of the hit result.

After that, the lottery target counter provided in the clear target area 371 in the work area 221 for specific control is set to "7" corresponding to the number of light emitting units provided in the universal figure display unit 38a (step SD210).

After that, a random number value is acquired from the universal figure random number circuit corresponding to the value of the lottery target counter (step SD211). In the present embodiment, the main control board 61 is provided with the number of random numbers circuits for general figures corresponding to the number of light emitting units provided in the general figure display section 38a. Specifically, since the public figure display section 38a is provided with seven light emitting sections, seven public figure random number circuits are provided. These seven random number circuits for universal figures have relatively short period cycles (for example, 1 microsecond to 7 microseconds) when the supply of the operating power to the main CPU 63 is started, and each of them is held by a different cycle. In this configuration, the backup power is supplied to stop the supply of the operating power to the main CPU 63 even when the supply of the operating power to the main CPU 63 is stopped. This is a configuration capable of storing and holding the random number value immediately before.

In the case where the seven light emitting units of the universal figure display unit 38a are first to seventh light emitting units and the seven random number circuits for universal figure are the random number circuits for first to seventh universal figure, The random number circuit for use corresponds to the first light emitting portion, the second random number circuit for universal figure corresponds to the second light emitting portion, the third random number circuit for universal figure corresponds to the third light emitting portion, The fourth universal figure random number circuit corresponds to the fourth light emitting section, the fifth universal figure random number circuit corresponds to the fifth light emitting section, and the sixth universal figure random number circuit corresponds to the sixth light emitting section. The random number circuit for the seventh universal figure corresponds to the seventh light emitting unit. Further, when the value of the lottery target counter is "7", it corresponds to the first light emitting unit and the first random number circuit for universal figures, and when the value of the lottery target counter is "6", the second It corresponds to the light-emitting unit and the second random number circuit for general purpose, and when the value of the lottery target counter is "5", it corresponds to the third light-emitting unit and the third random number circuit for general purpose, and the lottery target When the value of the counter is "4", it corresponds to the fourth light emitting unit and the fourth random number circuit for universal drawing, and when the value of the lottery target counter is "3", the fifth light emitting unit and the fourth light emitting unit. 5 If the value of the lottery target counter is “2”, it corresponds to the sixth light emitting unit and the sixth universal figure random number circuit, and the value of the lottery target counter is When the value is "1", it corresponds to the seventh light emitting unit and the seventh random number circuit for universal figure. It should be noted that the random number circuits for the first to seventh universal figures have the same numerical value range of random numbers (for example, "0 to 255").

After that, the lighting lottery process for the universal figure is executed (step SD212). In the normal drawing lighting lottery process, the general-purpose lighting lottery table is read from the main ROM 64. In the lighting lottery table for universal figures, half of the random number values that can be taken by the first to seventh universal figure random number circuits are set as winning random number values. Then, the random number value obtained in step SD211 is collated with the lighting lottery table for general figures.

When the result of the lighting lottery process for general drawings is a lighting win (step SD213: YES), the lighting information is displayed in the area corresponding to the current value of the lottery target counter in the clear target area 371 in the work area 221 for specific control. Is stored (step SD214). Each area provided corresponding to the lottery target counter is cleared to "0" when the process of step SD210 is executed.

Then, the value of the lottery target counter is decremented by 1 (step SD215), and it is determined whether the value of the lottery target counter after the decrement by 1 is "0" (step SD216). When a negative determination is made in step SD216, the processes of steps SD211 to SD215 are executed again.

If an affirmative decision is made in step SD216, the initial display data for a general figure is set in the third display data buffer 273 (step SD217). The initial display data for general drawings is determined by the presence/absence of lighting information corresponding to each of the lottery target counter values “1” to “7”. For example, while the lighting information corresponding to the values of the lottery target counter being "7", "5", and "1" is stored, the lighting information corresponding to the other values of the lottery target counter is not stored. In this case, the first light emitting portion, the third light emitting portion and the seventh light emitting portion of the universal figure display portion 38a are in the light emitting state, and the second light emitting portion, the fourth light emitting portion, the fifth light emitting portion and the sixth light emitting portion are Initial display data for a general figure that enables execution of the initial display for a general figure that is turned off is set in the third display data buffer 273.

By controlling the display of the public figure display unit 38a using the display data stored in the third display data buffer 273, the general figure display unit 38a performs the initial display corresponding to the display data. The display contents that can be displayed as the initial display on the public figure display unit 38a include the display contents that can be displayed on the public figure display unit 38a in the normal game, and the display contents that are not displayed on the public figure display unit 38a in the normal game. Contents are also included. In addition, as the display content that can be displayed on the public figure display unit 38a as an initial display and that can be displayed on the public figure display unit 38a in the normal game, the final content is displayed on the general figure display unit 38a in the variable display time of the deviation result. The general-purpose out-of-range display and the hit result variation display time include the general-purpose hit display finally displayed on the general-purpose display unit 38a.

After executing the processing of steps SD202 to SD217, "1" is set to the initial display flag 375 provided in the clear target area 371 in the work area 221 for specific control (step SD218).

If an affirmative decision is made in step SD201, or if the processing of step SD218 is executed, "1" is set to the display start flag provided in the clear target area 371 of the work area 221 for specific control (step SD219). .. The display start flag mainly determines whether or not the display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure reservation display unit 38a, and the general figure reservation display unit 38b should be started, as in the case of the 55th embodiment. This is a flag for specifying by the side CPU 63. When the value of the display start flag is "0", the main CPU 63 does not perform display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b. When the display start flag is set to "1", the main CPU 63 starts the display control of the special figure display section 37a, the special figure reservation display section 37b, the general figure display section 38a and the general figure reservation display section 38b.

Similar to the 55th embodiment, the display start flag is cleared to "0" in step SC204 of the main process (FIG. 185). The processing timing is after the supply of the operating power to the main CPU 63 is started, the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, the general figure reservation display unit 38b, and the first to fourth sections. The timing is earlier than the timing at which the second timer interrupt process (FIG. 188) for executing the display control of the notification display devices 201 to 204 is first executed. Then, in the display start process (FIG. 204) executed after the process at the start of supplying the operating power (step SC201 to step SC223) is completed, “1” is set to the display start flag. As a result, immediately after the supply of the operating power is resumed, the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b are maintained in the off state, and the supply of the operating power is performed. After the processing at the start (step SC201 to step SC223) is completed, the display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b is started.

In particular, in the display start process (FIG. 204), when either the first RAM clear process or the second RAM clear process is executed in the main process (FIG. 185) as already described, the special display in the first display data buffer 271 is performed. The initial display data for general purpose is set in the third display data buffer 273 while the initial display data for normal is set. In this case, if the display control of the special figure display unit 37a and the general figure display unit 38a is started immediately after the supply of the operating power to the main CPU 63 is started, the special figure display unit 37a and the general figure display unit are displayed. In 38a, the initial display will be started immediately after the display content immediately before the supply of the operating power is stopped is displayed. Then, the player visually observing such a change in the display content starts the initial display on the special figure display portion 37a and the general figure display portion 38a in the situation where either the first RAM clear processing or the second RAM clear processing is executed. You will be able to understand what was done. On the other hand, when the display data is set in the first display data buffer 271 and the third display data buffer 273 in the display start process (FIG. 204), the display start flag is set after the process of setting the display data ends. Is set to "1" and display of the special figure display portion 37a and the general figure display portion 38a is started. This makes it possible to prevent the display contents from changing as described above.

On the other hand, when "1" is set in the initial display flag 375 (step SD201: YES), the processes of steps SD202 to SD218 are not executed. Therefore, the first display data buffer 271 is in a state in which the display data stored immediately before the supply of the operating power is stopped is stored as it is, and the third display data buffer 273 is immediately before the supply of the operating power is stopped. The display data stored in is stored as it is. In this case, when the display start flag is set to "1" and the display of the special figure display portion 37a is started, the display data stored in the first display data buffer 271 immediately before the supply of the operating power is stopped. Is displayed on the special figure display portion 37a. When the display start flag is set to "1" and the display of the universal figure display unit 38a is started, the display data stored in the third display data buffer 273 is displayed immediately before the supply of the operating power is stopped. Corresponding display is performed on the public figure display unit 38a.

As described above in detail, when the first RAM clearing process is executed in the process (step SC201 to step SC223) at the start of supplying the operating power or when the second RAM clearing process of the set value updating process is executed, Since "1" is not set in the display flag 375, when the supply of operating power to the main CPU 63 is started and the display of the special figure display portion 37a and the general figure display portion 38a is started, these special characteristics are displayed. Initial display is started in the figure display section 37a and the general figure display section 38a. The initial display on the special figure display portion 37a is a pattern on the special figure display portion 37a when the entry of the game ball into the first operation opening 33 or the second operation opening 34 occurs and the start condition of the game time is satisfied. It continues until the variable display of is started. The initial display on the universal figure display portion 38a is continued until a game ball enters the through gate 35 and the variable display of the pattern on the universal figure display portion 38a is started. Even at the factory shipping stage, "1" is not set in the initial display flag 375, so that the special figure display portion 37a and the general figure display portion 38a start the dislocation display.

Whether the first RAM clearing process is executed or the second RAM clearing process of the set value updating process is executed as described above, the display on the special figure display unit 37a and the general figure display unit 38a is displayed. When the special figure display section 37a and the general figure display section 38a are initially displayed when the operation is started, supply of operating power is started and the display is performed on the special figure display section 37a and the general figure display section 38a. Even if the display contents of the display units 37a and 38a at the start are confirmed, it is not possible to grasp which of the first RAM clear process and the set value update process has been executed. As a result, even if the display contents of the special figure display unit 37a and the general figure display unit 38a when the supply of the operating power is started can be confirmed, it cannot be specified whether or not the set value updating process has been executed. It becomes possible to do.

When the first RAM clearing process and the second RAM clearing process of the set value updating process are not executed in the process (step SC201 to step SC223) at the start of supplying the operating power, the special figure display unit 37a starts displaying. In this case, the display content on the special figure display unit 37a is started with the display content immediately before the supply of the operating power is stopped, and the supply of the operating power is stopped when the display is started on the universal figure display unit 38a. The display content immediately before is started to be displayed on the universal figure display section 38a. That is, when the first RAM clearing process and the second RAM clearing process of the set value updating process are not executed in the process (step SC201 to step SC223) at the start of supplying the operating power, the special figure display unit 37a and the universal figure are displayed. The display content of the display unit 38a depends on the situation at the timing when the supply of the operating power is stopped, and the display content is various. On the other hand, when the first RAM clearing process or the second RAM clearing process of the set value updating process is executed in the process (step SC201 to step SC223) at the start of supplying the operating power, the special figure display unit 37a and the normal The initial display is determined and displayed by lottery on the diagram display unit 38a. As a result, even when the first RAM clearing process or the second RAM clearing process of the set value updating process is executed in the process (step SC201 to step SC223) at the start of supplying the operating power, the supply of the operating power is started. In the same manner as when the first RAM clearing process and the second RAM clearing process of the set value updating process are not executed in the process (step SC201 to step SC223), the display contents of the special figure display portion 37a and the general figure display portion 38a are displayed. It is possible to diversify. Therefore, even if the display of the special figure display portion 37a and the general figure display portion 38a is started when the supply of the operating power is started and the display is confirmed, either the first RAM clear processing or the second RAM clear processing is performed. It is possible to make it difficult to identify what has been executed.

In particular, when the display content of the initial display is determined, the lighting lottery process is executed for each light emitting unit for each of the special figure display section 37a and the general figure display section 38a. This makes it possible to diversify the display contents that can be selected as the initial display.

It should be noted that the processing of steps SD202 to SD218 of the display start processing (FIG. 204) is executed even when the first RAM clear processing and the second RAM clear processing are not executed when the supply of the operating power is started. Good. In this case, even if the special figure display portion 37a and the universal figure display portion 38a are confirmed when the supply of the operating power is started, the first RAM clear processing and the second RAM clear processing are performed when the supply of the operating power is started. It becomes possible to make it impossible to specify whether or not any one has been executed. Further, in the configuration, if the variation display of the pattern is being executed on the special figure display portion 37a immediately before the supply of the operating power is stopped or if it is in the opening/closing execution mode, the display is started. The display of the display content before the supply of the operating power is stopped may be restarted by the special figure display unit 37a by not executing the processing of step SD202 to step SD209 of the processing (FIG. 204). .. In addition, when the variable display of the pattern is being executed on the universal graphic display unit 38a immediately before the supply of the operating power is stopped or when the universal power is open, the display start process ( It may be configured such that the display of the display content before the supply of the operating power is stopped is restarted by the special figure display unit 37a by not executing the processing of step SD210 to step SD217 of FIG.

Further, in the special drawing lighting lottery process (step SD204) of the display start process (FIG. 204), a lottery of whether or not to individually light each of the light emitting units of the special figure display unit 37a is performed. A configuration may be adopted in which a lottery is performed to determine whether or not to light a predetermined plurality of units such as two or three. Further, in the drawing lottery process (step SD212) for the general figure of the display start process (FIG. 204), the lottery for whether or not to individually light each of the light emitting units of the general figure display unit 38a is not performed. A configuration may be adopted in which a lottery is performed to determine whether or not to light a predetermined plurality of units such as two or three.

When the first RAM clearing process is executed when the supply of the operating power is started, steps SD202 to SD217 of the display starting process (FIG. 204) are executed, while the second RAM clearing process is executed. In this case, the steps SD202 to SD217 of the display start processing (FIG. 204) may not be executed. Further, when the second RAM clearing process is executed when the supply of the operating power is started, the steps SD202 to SD217 of the display starting process (FIG. 204) are executed, while the first RAM clearing process is executed. In this case, the steps SD202 to SD217 of the display start processing (FIG. 204) may not be executed.

<62nd Embodiment>
In the present embodiment, the display contents of the special figure display portion 37a and the general figure display portion 38a when the supply of the operating power to the main CPU 63 is started are different from those in the 58th embodiment. Hereinafter, a configuration different from that of the 58th embodiment will be described. The description of the same configuration as the 58th embodiment is basically omitted.

FIG. 205 is a flowchart showing the setting value update processing in this embodiment executed in step SC216 in the main processing (FIG. 185) of the main CPU 63. Note that the processing of steps SD301 to SD316 in the setting value update processing is executed by using the specific control program and specific control data in the main CPU 63.

First, interrupt permission is set (step SD301). As a result, the first timer interrupt process (FIG. 196) is interrupted and activated in the first interrupt cycle, and the second timer interrupt process (FIG. 188) is interrupted and activated in the second interrupt period.

In the present embodiment, the interrupts of the first timer interrupt process (FIG. 196) and the second timer interrupt process (FIG. 188) are basically prohibited in the process (step SC201 to step SC223) at the start of supply of operating power. In the setting confirmation process (step SC213) and the set value update process (FIG. 205), interruption is permitted. Therefore, in the situation where the setting confirmation process (step SC213) and the set value update process (FIG. 205) are not executed in the process (step SC201 to step SC223) at the start of supplying the operating power, the first timer interrupt process (FIG. 196) and the second timer interrupt process (FIG. 188) are prohibited, and the setting confirmation process (step SC213) or the set value update process (FIG. 205) is being executed, the first timer interrupt process (FIG. 196). ) And the execution of the second timer interrupt process (FIG. 188) are permitted. However, in the situation where the setting confirmation process (step SC213) or the setting value update process (FIG. 205) is being executed, the start-up processing flag is set to “1”, so the first timer interrupt process (FIG. Even if 196) is activated, among the various processes of the first timer interrupt process (FIG. 196), the processes for power failure monitoring, updating various counters, and fraudulent monitoring are executed, while the game progresses. The first timer interrupt process (FIG. 196) is terminated without executing the process.

After that, the setting update display flag provided in the specific control work area 221 is set to "1" on condition that "1" is not set (step SD302). When the setting update display flag is set to "1", a positive determination is made in step SC402 of the second timer interrupt process (FIG. 188), and the setting process for the fifth display data buffer 275 during the setting update is performed. (Step SC403) is executed. The processing content of the setting processing for the fifth display data buffer 275 during the setting update is the same as that in the 45th embodiment. By executing the process, as shown in the explanatory view of FIG. 124(a), for example, a display indicating that the setting value of the pachinko machine 10 is being updated and selection as an update target of the pachinko machine 10 are made. The displayed set values are displayed on the first to fourth notification display devices 201 to 204.

After that, initial setting at the start is performed (step SD303). In the initial setting, the game stop flag provided in the work area 221 for specific control is cleared to "0". As for the game stop flag, when the power failure flag is not set to "1" because the power failure process was not properly performed at the previous power shutdown (step SC205: NO), the specific control work area 221 and If the checksums do not match due to a change in the storage state of information since the last power-off of at least one of the stack areas 222 for specific control (step SC206: NO), or the setting reference area 341 This is a flag that is set to "1" in step SC220 of the main process (FIG. 185) when the set value corresponding to the information stored in is not in the normal range (step SC207: NO). When the game stop flag is set to "1", the processing of steps SC701 to SC706 is executed in the first timer interrupt processing (FIG. 196), while the positive determination is made in step SC707 to step SC708 to step SC708. The process of SC722 is not executed. As a result, when the information abnormality of the main RAM 65 as described above occurs, the processing for performing the power failure monitoring, the updating of various counters and the illegality monitoring is executed, while the processing for advancing the game is executed. Will not be done. By clearing the game stop flag to "0" in the process of step SD303, the state in which the occurrence of the information abnormality of the main RAM 65 is specified is canceled when the set value update process (FIG. 205) is executed. Is possible.

After that, "1" is set in the setting update area 342 (see FIG. 154) in the specific control work area 221 (step SD304). The setting update area 342 is a storage area for storing information on the setting value being updated in the setting value updating process (FIG. 205) as in the 45th embodiment. When the numerical information of “1” is stored in the setting update area 342, the set value of the update target (selection target or change target) is “setting 1”. When the numerical information of “2” is stored in the setting update area 342, the setting value to be updated is “setting 2”. When the numerical information of “3” is stored in the setting update area 342, the setting value to be updated is “setting 3”. When the numerical information of "4" is stored in the setting update area 342, the setting value to be updated is "setting 4". When the numerical information of "5" is stored in the setting update area 342, the setting value to be updated is "setting 5". When the numerical information of “6” is stored in the setting update area 342, the setting value to be updated is “setting 6”.

By setting "1" in the setting update area 342 in step SD304, the setting value to be updated becomes "setting 1". That is, in the present embodiment, the setting value to be updated is “setting 1” when the setting value updating process (FIG. 205) is started, whichever setting value the pachinko machine 10 currently has.

Then, the update start command is transmitted to the voice emission control device 81 (step SD305). Upon receiving the update start command, the sound emission control device 81 displays an image showing that the setting value update processing (FIG. 205) is being executed, and an image for making it possible to recognize the operation content for changing the setting value. , And the display control device 82 so as to display an image for recognizing the operation content for ending the setting value update process (FIG. 205) on the symbol display device 41. This allows the manager of the game hall to recognize that the setting value is being changed, and the operation content and the setting value update process necessary to change the setting value (FIG. 205). It becomes possible for the manager of the game hall to recognize the operation content necessary for ending the game. In addition to or instead of the above-mentioned notification being performed by the symbol display device 41, at least one of the display light emitting unit 53 and the speaker unit 54 may be configured. Further, a configuration may be adopted in which an external output indicating that the set value update processing (FIG. 205) is being executed is performed to a device outside the pachinko machine 10, such as a game hall management computer.

After that, it is determined whether or not the setting value information stored in the setting update area 342 is any one of "1" to "6" (step SD306). If it is not any of "1" to "6" (step SD306: NO), "1" is set in the setting update area 342 (step SD307). As a result, the setting value to be updated becomes “setting 1”.

When an affirmative judgment is made in step SD306 or the processing of step SD307 is executed, it is judged whether or not the setting key inserting section 68a has switched from the ON state to the OFF state by using the setting key (step SD308). Specifically, it is determined whether the reception state of the signal received from the detection sensor that detects the state of the setting key insertion unit 68a has changed from the reception state corresponding to the ON state to the reception state corresponding to the OFF state. To do. Therefore, the OFF state is maintained not only when the setting key inserting section 68a is maintained in the ON state, but also when the setting value updating process is started in the situation where the setting key inserting section 68a is in the OFF state. Also in this case, a negative determination is made in step SD308.

When a negative determination is made in step SD308, the value of the setting update area 342 is incremented by 1 on the condition that the reset button 68c is pressed (step SD309: YES) (step SD310). As a result, each time the reset button 68c is pressed once, the setting value is updated by one step. When the reset button 68c is not pressed (step SD309: NO) or when the value of the setting update area 342 is incremented by 1, the process returns to step SD306, but the setting update is performed in step SD306. When it is determined that the value of the use area 342 is 7 or more, “1” is set in the setting update area 342 in step SD307. As a result, when the reset button 68c is pressed once in the situation of "setting 6", the process returns to "setting 1".

When it is specified that the setting key insertion unit 68a has switched from the ON state to the OFF state (step SD308: YES), the setting value corresponding to the information stored in the setting update area 342 is stored in the setting reference area 341. By determining whether or not the set value corresponding to the set information is equal to or more than the set value, the set value equal to or higher than the advantage of the set value selected before the current set value update process (FIG. 205) is started is determined. It is determined whether or not it has been selected in the current setting value update processing (FIG. 205) (step SD311). When an affirmative determination is made in step SD311, "1" is set to the rising expectation flag provided in the clear target area 371 in the work area 221 for specific control (step SD312). The increase expectation flag indicates whether or not the set value that is equal to or higher than the advantage of the set value that has been selected by the process at the time of starting the supply of the operating power this time (step SC201 to step SC223) is set. This is a flag for specifying by the CPU 63.

If a negative determination is made in step SD311 or if the processing in step SD312 is executed, the setting reference area 341 is overwritten with the setting value information stored in the setting update area 342 (step SD313). As a result, the setting value information obtained as a result of the update in the setting value updating process this time (FIG. 205) is set in the setting reference area 341, and the setting value corresponding to the set information is the current state. It becomes the set value of the pachinko machine 10.

After that, the interruption is prohibited (step SD314). As a result, when the set value updating process (FIG. 205) is terminated and the process returns to the process (step SC201 to step SC223) at the start of supply of the operating power in the main process (FIG. 185), the first timer interrupt process (FIG. 196) and the interrupt of the second timer interrupt processing (FIG. 188) are prohibited.

After that, the second RAM clearing process is executed (step SD315). In the second RAM clearing process, similarly to the first RAM clearing process (step SC218) of the main process (FIG. 185), the area provided in the clearing target area 371 in the specific control work area 221 is cleared to “0” and initialized. Execute the setting. The area in which the setting value information indicating the setting state of the pachinko machine 10 is set (that is, the setting reference area 341) is provided not in the clear target area 371 but in the clear target area 372.

After that, a return command for updating is transmitted to the voice emission control device 81 (step SD316). The voice emission control device 81 receives the return command at the time of update to identify that the process at the start of supplying the operating power (step SC201 to step SC223) has been completed in the main CPU 63, and It is specified that the set value update process (FIG. 205) has been executed in the process at the start of supply (step SC201 to step SC223). Then, similar to the forty-ninth embodiment, the processing corresponding to the reception of the update return command is executed.

FIG. 206 is a flowchart showing the display start processing in this embodiment executed by the main CPU 63. The processes of steps SD401 to SD413 in the display start process are executed by using the specific control program and the specific control data in the main CPU 63.

When "1" is not set in the initial display flag 375 (step SD401: NO), it is determined whether or not "1" is set in the rising expectation flag of the clear target area 371 in the specific control work area 221. The determination is made (step SD402). When "1" is not set in the rising expectation flag (step SD402: NO), the first display allocation table 391 for special drawings provided in the main ROM 64 is read (step SD403), and the rising expectation flag is set to " If "1" is set (step SD402: YES), the second display allocation table 392 for special drawings provided in the main ROM 64 is read (step SD404).

207(a) is an explanatory diagram for explaining the first display allocation table 391 for special drawings, and FIG. 207(b) is an explanatory diagram for explaining the second display allocation table 392 for special drawings. It is a figure. In both the first display distribution table 391 for special maps and the second display distribution table 392 for special maps, the first initial display data for special maps and the initial display data for special maps are used as initial display data for special maps. The second initial display data and the third initial display data for special drawings are present.

The first initial display data for the special figure is data for displaying the first initial display for the special figure on the special figure display portion 37a, and the second initial display data for the special figure is the second initial for the special figure. The data is data for displaying the display on the special figure display portion 37a, and the third initial display data for special figure is data for displaying the third initial display for special figure on the special figure display portion 37a. The display contents of the first initial display for special characters, the second initial display for special characters, and the third initial display for special characters are different from each other.

The first initial display data for the special figure, the second initial display data for the special figure, and the third initial display data for the special figure are the stop result setting process for the jackpot result in the special figure variation start process (FIG. 13) (step This is the display data that is not selected in either the step S507) or the stop result setting process for the disconnection result (step S509). Therefore, the first initial display for special maps, the second initial display for special maps, and the third initial display for special maps are different from the display contents that can be finally stopped and displayed on the special map display portion 37a at the game time. ing. Furthermore, the first initial display for special drawing, the second initial display for special drawing, and the third initial display for special drawing are displayed when the variable display of the picture is performed on the special drawing display portion 37a at the game time. The display contents are not selected as. As a result, the supply of operating power to the main CPU 63 is started, and at the time of starting the display in the special figure display portion 37a, the first initial display for the special figure, the second initial display for the special figure, and the third initial point for the special figure. If any of the initial displays is performed, one of the first RAM clearing process and the second RAM clearing process of the set value updating process is performed in the process (step SC201 to step SC223) at the start of the supply of the operating power this time. It is possible to know what has been executed.

As shown in FIGS. 207(a) and 207(b), the first display allocation table 391 for special maps and the second display allocation table 392 for special maps respectively include the first display allocation table 391 for special drawings. The numerical range of the initial display counter 381 for special drawings is set for each of the third initial display data. Since the special display initial display counter 381 is provided in the non-clearing target area 372 as in the case of the 58th embodiment, it is stored in the main RAM 65 when the supply of operating power to the main CPU 63 is stopped. If the backup power is continuously supplied, the numerical value immediately before the supply of the operating power is stopped without being initialized even if the first RAM clearing process or the second RAM clearing process of the set value updating process is executed. The state in which the information is stored is maintained. Further, the numerical information of the initial display counter 381 for special figures is updated in step SC706 in the first timer interrupt processing (FIG. 196) as in the 58th embodiment.

In the special display first display allocation table 391, as shown in FIG. 207(a), the special display initial display counter 381 of "0 to 39" is added to the special display first initial display data. The numerical range is set, the numerical range of the special display initial display counter 381 of “40 to 54” is set for the second special display data for special drawing, and the third initial for special drawing is set. For the display data, the numerical range of the initial display counter 381 for special drawings of “55 to 59” is set. In other words, in the special display first display allocation table 391, the selection probability of the special initial first display data is ⅔, so that the selection probability is highest, and the special initial second display is selected. The selection probability of the data is 1/4, so that the selection probability is second highest, and the selection probability of the third initial display data for special drawing is 1/12, the selection probability is the lowest.

In the special display second display allocation table 392, as shown in FIG. 207(b), the special display initial display counter 381 of “0 to 9” is added to the special display first initial display data. The numerical range is set, the numerical range of the special display initial display counter 381 of "10 to 39" is set for the second initial display data for special drawing, and the third initial for special drawing is set. For the display data, the numerical range of the initial display counter 381 for special drawings of "40 to 59" is set. That is, in the special display second display allocation table 392, the selection probability of the second initial display data for special drawing is 1/2, so that the selection probability is highest, and the third initial display for special drawing is displayed. The selection probability of data is ⅓, which is the second highest selection probability, and the selection probability of the first initial display data for special drawing is ⅙, which is the lowest selection probability.

Returning to the description of the display start process (FIG. 206 ), after performing the process of step SD403 or the process of step SD404, the lottery process of initial display data for special figures is executed (step SD405). In the lottery process for initial display data for special maps, the current numerical information of the initial display counter 381 for special maps is acquired. Then, the special display first display allocation table 391 for which the acquired numerical information is read from the main ROM 64 in step SD403 or the special display second display allocation table for which the numerical information is read from the main ROM 64 in step SD404. By collating with 392, the display data to be displayed this time is selected from the first initial display data for special drawing, the second initial display data for special drawing, and the third initial display data for special drawing. select.

The display data selected in the lottery process of the initial display data for special maps is set in the first display data buffer 271 (step SD406). By controlling the display of the special figure display unit 37a using the display data stored in the first display data buffer 271, an initial display corresponding to the display data is performed on the special figure display unit 37a. That is, when the first initial display data for special drawing is set in the first display data buffer 271, the first initial display for special drawing is performed on the special drawing display portion 37a, and the first display data buffer 271 is displayed. If the second initial display data for special drawing is set to the special drawing, the second initial display for special drawing is performed in the special drawing display portion 37a, and the third initial for special drawing is displayed in the first display data buffer 271. When the display data is set, the special initial display 37a displays the third initial display for special drawings.

Then, it is determined whether or not "1" is set in the rising expectation flag of the clear target area 371 in the specific control work area 221 (step SD407). When "1" is not set in the rising expectation flag (step SD407: NO), the first display distribution table 393 for general figures provided in the main ROM 64 is read (step SD408), and the rising expectation flag is set. When "1" is set (step SD407: YES), the second display allocation table 394 for general drawings provided in the main ROM 64 is read (step SD409).

207(c) is an explanatory diagram for explaining the first display distribution table 393 for general drawings, and FIG. 207(d) is a description for explaining the second display distribution table 394 for general drawings. It is a figure. In both the first display sorting table 393 for general drawings and the second display sorting table 394 for general drawings, the first initial display data for general drawings and the first initial display data for general drawings are used as initial display data for general drawings. There is the second initial display data and the third initial display data for general drawings.

The first initial display data for general drawings is data for displaying the first initial display for general drawings on the general drawing display unit 38a, and the second initial display data for general drawings is the second initial display data for general drawings. The display is data for displaying on the public figure display unit 38a, and the third initial display data for public figure is data for displaying the third initial display for general figure on the public figure display unit 38a. The display contents of the first initial display for general drawings, the second initial display for general drawings, and the third initial display for general drawings are different from each other.

The first initial display data for the universal figure, the second initial display data for the universal figure, and the third initial display data for the universal figure are the universal figure universal communication control process (step SC716) in the first timer interrupt process (FIG. 196). ) In the case where the result of the general electric open lottery executed by using the general electric utility object opening counter C4 to determine whether or not to open the general electric utility object 34a is a miss result, and the winning result The display data is not selected in any of the cases. Therefore, the first initial display for public figures, the second initial display for general figures, and the third initial display for general figures are the display contents that can be finally stopped and displayed on the general figure display unit 38a in the variable display time. Different. Furthermore, the first initial display for public figures, the second initial display for public figures, and the third initial display for general figures are displayed when the variable display of the pattern is performed on the general figure display unit 38a in the variable display time. It is the display content that is not selected as the target. As a result, the supply of operating power to the main CPU 63 is started, and when the display on the universal figure display unit 38a is started, the first initial display for the universal figure, the second initial display for the universal figure and the third initial display for the universal figure. If any of the initial displays is performed, one of the first RAM clearing process and the second RAM clearing process of the set value updating process is performed in the process (step SC201 to step SC223) at the start of the supply of the operating power this time. It is possible to know what has been executed.

As shown in FIGS. 207(c) and 207(d), the first display sorting table 393 for general drawings and the second display sorting table 394 for general drawings each have a first display sorting table for general drawings. The numerical range of the general-purpose initial display counter 382 is set for each of the third initial display data. The general-purpose initial display counter 382 is provided in the non-clearing target area 372 as in the case of the 58th embodiment. Therefore, in the situation where the supply of operating power to the main CPU 63 is stopped, the main RAM 65 is displayed. If the backup power is continuously supplied, the numerical value immediately before the supply of the operating power is stopped without being initialized even if the first RAM clearing process or the second RAM clearing process of the set value updating process is executed. The state in which the information is stored is maintained. Further, the numerical information of the general-purpose initial display counter 382 is updated in step SC708 in the first timer interrupt processing (FIG. 196) as in the 58th embodiment.

In the first display distribution table 393 for general drawings, as shown in FIG. 207(c), the initial display counter 382 for general drawings of "0 to 29" is added to the first initial display data for general drawings. The numerical range is set, and the numerical range of the initial display counter 382 for a general figure of “30 to 49” is set for the second initial display data for a general figure, and the third initial for general figure is set. A numerical range of the general-purpose initial display counter 382 of "50 to 59" is set for the display data. That is, in the general-purpose first display allocation table 393, the selection probability of the general-purpose first initial display data is 1/2, so that the selection probability is the highest, and the general-purpose second initial display data is ½. The selection probability of the data is ⅓, so that the selection probability is second highest, and the selection probability of the third initial display data for general drawings is ⅙, the lowest selection probability.

In the second display distribution table 394 for a general figure, as shown in FIG. 207(d), the initial display counter 382 for a general figure of “0 to 19” is added to the first initial display data for a general figure. A numerical range is set, and a numerical range of the initial display counter 382 for a general figure of "20 to 29" is set for the second initial display data for a general figure, and the third initial for a general figure is set. A numerical range of the general-purpose initial display counter 382 of "30 to 59" is set for the display data. That is, in the second display distribution table 394 for a general figure, the selection probability of the third initial display data for a general figure is 1/2, so the selection probability is highest, and the first initial display for a general figure is The selection probability of the data is ⅓, so that the selection probability is second highest, and the selection probability of the second initial display data for general purpose is ⅙, the lowest selection probability.

Returning to the description of the display start process (FIG. 206 ), after the process of step SD 408 or the process of step SD 409 is executed, the lottery process of initial display data for universal graphics is executed (step SD 410 ). In the lottery process for initial display data for a general figure, the current numerical value information of the initial display counter 382 for a general figure is acquired. Then, the obtained numerical value information is read from the main ROM 64 in the main ROM 64 at the first display distribution table 393 for general drawings or in Step SD409 the general display second display distribution table is read from the main ROM 64 in step SD409. By collating with 394, the display data to be displayed this time is selected from the first initial display data for general drawings, the second initial display data for general drawings, and the third initial display data for general drawings. select.

The display data selected in the lottery process of the initial display data for general drawings is set in the third display data buffer 273 (step SD411). By controlling the display of the public figure display unit 38a using the display data stored in the third display data buffer 273, the general figure display unit 38a performs the initial display corresponding to the display data. That is, when the first initial display data for a general figure is set in the third display data buffer 273, the first initial display for a general figure is performed on the general figure display section 38a, and the third display data buffer 273 is displayed. If the second initial display data for a public figure is set in the, the second initial display for a general figure is performed in the general figure display unit 38a, and the third initial for a general figure is displayed in the third display data buffer 273. When the display data is set, the third figure display for a figure is performed on the figure display portion 38a.

After performing the processing of steps SD402 to SD411, "1" is set to the initial display flag 375 provided in the clear target area 371 in the specific control work area 221 (step SD412).

If an affirmative decision is made in step SD401, or if the processing of step SD412 is executed, "1" is set to the display start flag provided in the clear target area 371 of the work area 221 for specific control (step SD413). .. The display start flag mainly determines whether or not the display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure reservation display unit 38a, and the general figure reservation display unit 38b should be started, as in the case of the 55th embodiment. This is a flag for specifying by the side CPU 63. When the value of the display start flag is "0", the main CPU 63 does not perform display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b. When the display start flag is set to "1", the main CPU 63 starts the display control of the special figure display section 37a, the special figure reservation display section 37b, the general figure display section 38a and the general figure reservation display section 38b.

Similar to the 55th embodiment, the display start flag is cleared to "0" in step SC204 of the main process (FIG. 185). The processing timing is after the supply of the operating power to the main CPU 63 is started, the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, the general figure reservation display unit 38b, and the first to fourth sections. The timing is earlier than the timing at which the second timer interrupt process (FIG. 188) for executing the display control of the notification display devices 201 to 204 is first executed. Then, in the display start processing (FIG. 206) executed after the processing at the start of supplying the operating power (step SC201 to step SC223) is completed, the display start flag is set to “1”. As a result, immediately after the supply of the operating power is resumed, the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b are maintained in the off state, and the supply of the operating power is performed. After the processing at the start (step SC201 to step SC223) is completed, the display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b is started.

In particular, in the display start processing (FIG. 206), as described above, when either the first RAM clear processing or the second RAM clear processing is executed in the main processing (FIG. 185), the special display in the first display data buffer 271 is performed. Any one of the first to third initial display data for general purpose is set, and any one of the first to third initial display data for general purpose is set to the third display data buffer 273. In this case, if the display control of the special figure display unit 37a and the general figure display unit 38a is started immediately after the supply of the operating power to the main CPU 63 is started, the special figure display unit 37a and the general figure display unit are displayed. In 38a, the initial display will be started immediately after the display content immediately before the supply of the operating power is stopped is displayed. On the other hand, when the display data is set in the first display data buffer 271 and the third display data buffer 273 in the display start process (FIG. 206), the display start flag is set after the process of setting the display data ends. Is set to "1" and the special figure display portion 37a and the general figure display portion 38a are displayed. This makes it possible to prevent the display contents from changing as described above.

On the other hand, when "1" is set in the initial display flag 375 (step SD401: YES), the processes of steps SD402 to SD412 are not executed. Therefore, the first display data buffer 271 is in a state in which the display data stored immediately before the supply of the operating power is stopped is stored as it is, and the third display data buffer 273 is immediately before the supply of the operating power is stopped. The display data stored in is stored as it is. In this case, when the display start flag is set to "1" and the display of the special figure display portion 37a is started, the display data stored in the first display data buffer 271 immediately before the supply of the operating power is stopped. Is displayed on the special figure display portion 37a. When the display start flag is set to "1" and the display of the universal figure display unit 38a is started, the display data stored in the third display data buffer 273 is displayed immediately before the supply of the operating power is stopped. Corresponding display is performed on the public figure display unit 38a.

As described above in detail, when the first RAM clearing process is executed in the process (step SC201 to step SC223) at the start of supplying the operating power or when the second RAM clearing process of the set value updating process is executed, Since "1" is not set in the display flag 375, when the supply of operating power to the main CPU 63 is started and the display of the special figure display portion 37a and the general figure display portion 38a is started, these special characteristics are displayed. Initial display is started in the figure display section 37a and the general figure display section 38a. The initial display on the special figure display portion 37a is a pattern on the special figure display portion 37a when the entry of the game ball into the first operation opening 33 or the second operation opening 34 occurs and the start condition of the game time is satisfied. It continues until the variable display of is started. The initial display on the universal figure display portion 38a is continued until a game ball enters the through gate 35 and the variable display of the pattern on the universal figure display portion 38a is started. Even at the factory shipping stage, since "1" is not set in the initial display flag 375, the initial display is started on the special figure display portion 37a and the general figure display portion 38a.

Whether the first RAM clearing process is executed or the second RAM clearing process of the set value updating process is executed as described above, the display on the special figure display unit 37a and the general figure display unit 38a is displayed. When the special figure display section 37a and the general figure display section 38a are initially displayed when the operation is started, supply of operating power is started and the display is performed on the special figure display section 37a and the general figure display section 38a. Even if the display contents of the display units 37a and 38a at the start are confirmed, it is not possible to grasp which of the first RAM clear process and the set value update process has been executed. As a result, even if the display contents of the special figure display unit 37a and the general figure display unit 38a when the supply of the operating power is started can be confirmed, it cannot be specified whether or not the set value updating process has been executed. It becomes possible to do.

On the other hand, when the set value update process (FIG. 205) is executed and a set value that is equal to or higher than the advantage of the set values so far is selected in the set value update process (FIG. 205), the special figure display unit 37a. The second display allocation table 392 for special drawings is selected as the table for determining the initial display to be performed on the other hand, whereas the setting value update processing (FIG. 205) is not executed or the setting value update is performed. As a table for determining the initial display to be displayed on the special figure display portion 37a when the set value equal to or higher than the advantage of the set values is not selected in the process (FIG. 205) The display allocation table 391 is selected. The first display allocation table 391 for special maps and the second display allocation table 392 for special maps have different initial display selection modes. Thus, by confirming the contents of the initial display when the supply of the operating power is started and the display of the special figure display portion 37a is started, a new set value equal to or higher than the advantage of the set values up to that time is newly set. It is possible to predict whether or not it has been done.

Similarly, when the set value update process (FIG. 205) is executed and a set value that is equal to or higher than the advantage of the set values up to that time is selected in the set value update process (FIG. 205), the general setting is performed. The second display allocation table 394 for general drawings is selected as the table for determining the initial display to be performed on the display unit 38a, whereas the setting value update processing (FIG. 205) is not executed, or As a table for determining an initial display to be displayed on the figure display unit 38a when a set value equal to or higher than the advantage of the set values is not selected in the set value update process (FIG. 205) The first display allocation table 393 is selected. The first display allocation table 393 for general drawings and the second display allocation table 394 for general drawings have different initial display selection modes. With this, by confirming the contents of the initial display when the supply of the operating power is started and the display of the general-purpose display unit 38a is started, the set value more than the advantage of the set values up to that time is newly set. It is possible to predict whether or not it has been done.

In addition, as described above, it is possible to predict whether or not a new set value equal to or higher than the advantage of the set values up to that time is newly set according to the contents of the initial display when the supply of the operating power is started and the display is started. There are a plurality of display sections, that is, a special figure display section 37a and a general figure display section 38a as possible display sections. As a result, the number of judgments for predicting whether or not a set value that is equal to or higher than the advantage of the set values up to that time is newly set increases, so that it is possible to improve the accuracy of the prediction by the player. ..

In addition, in the set value update process (FIG. 205), when the set value equal to or higher than the advantage of the set values up to that time is set, the rising expectation flag is set to "1", and the special display is used for the initial display data lottery. The configuration is not limited to the configuration in which the second display distribution table 392 or the general-purpose second display distribution table 394 is referred to, and is more advantageous in the set value update processing (FIG. 205) than the set values up to that point. When the set value is set, the rising expectation flag is set to "1", and the second display distribution table 392 for special drawings or the second display distribution table 394 for general drawings is referred to when the initial display data is selected. When the setting value updating process (FIG. 205) is executed, the rising expectation flag is set to "1" regardless of which setting value is newly set, and the initial display data is selected by lottery. At this time, the second display allocation table 392 for special drawings or the second display allocation table 394 for general drawings may be referred to.

Further, initial display data for special maps that can be selected when the first display distribution table 391 for special maps is referred to, and special maps that can be selected when the second display distribution table 392 for special maps is referred to. It is not limited to the configuration in which the initial display data for special use completely matches, and the initial display data for special use and the special display for special use set in the first display allocation table 391 for special use The configuration may be such that the initial display data for special maps set in the second display distribution table 392 does not completely match. In this case, the display content of the special figure display portion 37a is clearly different depending on whether or not "1" is set in the rising expectation flag in the set value update processing (FIG. 205). Therefore, by confirming the display content of the special figure display portion 37a when the supply of the operating power is started, it is possible to clearly specify whether or not the set value equal to or higher than the advantage of the set values up to that time is set. Is possible.

In addition, although the initial display data for special maps, which is common to the first display allocation table 391 for special maps and the second display allocation table 392 for special maps, is set, The first display allocation table 391 and the special display second display allocation table 392 may have one of the initial display data for special maps which is not set to the other. In this case, when the initial display corresponding to the initial display data for special maps which is set only in the first display allocation table 391 for special maps is executed by the special map display portion 37a, the setting up to that time is performed. It is possible to specify that the set value equal to or higher than the value advantage is not set. On the other hand, when the initial display corresponding to the initial display data for special maps which is set only in the second display allocation table 392 for special maps is executed in the special map display portion 37a, the setting up to that time is performed. It is possible to specify that the set value equal to or higher than the value advantage is set.

In addition, initial display data for a public figure that can be selected when referring to the first display sorting table 393 for public figures and public chart that can be selected when referring to the second display sorting table 394 for public figures It is not limited to the configuration in which the initial display data for a normal picture completely matches, and the initial display data for a general picture set for the first display distribution table 393 for a general picture and the general display The configuration may be such that the general display initial display data set in the second display distribution table 394 does not completely match. In this case, the display content of the general figure display portion 38a is clearly different depending on whether or not the rising expectation flag is set to "1" in the set value update processing (FIG. 205). Therefore, by confirming the display content of the universal figure display unit 38a when the supply of the operating power is started, it is possible to clearly specify whether or not the set value equal to or higher than the advantage of the set values up to that time has been set. Is possible.

In addition, although common initial display data for general drawings is set for the first display allocation table 393 for general drawings and the second display allocation table 394 for general drawings, The first display allocation table 393 and the general display second display allocation table 394 may be configured to include the initial display data for general purpose that is set in one side and not set in the other side. In this case, if the initial display corresponding to the initial display data for a general figure set only in the first display allocation table 393 for a general figure is executed by the general figure display unit 38a, the settings up to that time are performed. It is possible to specify that the set value equal to or higher than the value advantage is not set. On the other hand, when initial display corresponding to the initial display data for general figures set only in the second general-purpose picture display table 394 for general figures is executed in the general figure display unit 38a, the settings up to that time are performed. It is possible to specify that the set value equal to or higher than the value advantage is set.

The initial display data for special maps is not limited to the configuration determined by the lottery, and the initial display data for special maps selected when the rising expectation flag is set to 1 is 1 There is only one type, and the initial display data for special maps selected when "1" is not set in the rising expectation flag is only one type, and the initial display data for each special map is different. It may be configured to have. In this case, the display content of the special figure display portion 37a varies depending on whether or not the set value equal to or higher than the advantage of the set values up to that time is set.

Further, the initial display data for the general figure is not limited to the configuration determined by the lottery, and the initial display data for the general figure selected when "1" is set in the rising expectation flag is 1 There is only one type, and the initial display data for general drawings that is selected when "1" is not set in the rising expectation flag is only one type, and the initial display data for each general drawing is different. It may be configured to have. In this case, the display content of the general figure display unit 38a differs depending on whether or not the set value equal to or higher than the advantage of the set values up to that time is set.

<63rd Embodiment>
In the present embodiment, the display contents of the special figure display portion 37a and the general figure display portion 38a when the supply of operating power to the main CPU 63 is restarted are different from those in the 62nd embodiment. The configuration different from that of the 62nd embodiment will be described below. Note that the description of the same configuration as the 62nd embodiment is basically omitted.

FIG. 208 is a flowchart showing the display start processing in this embodiment executed by the main CPU 63. The processes of steps SD501 to SD514 in the display start process are executed by using the specific control program and the specific control data in the main CPU 63.

When "1" is not set in the initial display flag 375 (step SD501: NO), the initial display lottery process is executed (step SD502). In the lottery process for initial display, the same process as step SD402 to step SD411 of the display start process (FIG. 206) in the 62nd embodiment is executed. As a result, when the first RAM clearing process or the second RAM clearing process of the set value updating process is executed, the display of the special figure display unit 37a and the general figure display unit 38a is started as in the above-described 62nd embodiment. In some cases, initial display is performed. Then, "1" is set to the initial display flag 375 (step SD503).

When "1" is set in the initial display flag 375 (step SD501: YES), information indicating whether or not the game game is being executed in the clear target area 371 of the specific control work area 221 is stored. By referring to the storage area, it is determined whether or not the situation in which the supply of the operating power is resumed after the supply of the operating power is stopped during the execution of the game game (step SD504). Information indicating that the game time is being executed is stored in the storage area when the game time is started, and information indicating that the game time is being executed is stored when the game time is ended. Erased from the area. The information in the storage area is stored and retained when the backup power is supplied to the work area 221 for specific control even if the supply of the operating power to the main CPU 63 is stopped, and the operation to the main CPU 63 is performed. When the first RAM clearing process and the second RAM clearing process are not executed when the power supply is restarted, they are stored and held.

In addition, by referring to the storage area in the clear target area 371 of the work area 221 for specific control that stores information indicating whether the open/close execution mode is being executed, the operating power during the open/close execution mode is being executed. It is determined whether or not the supply of operating power has been restarted after the supply of power has been stopped (step SD505). The storage area stores information indicating that the opening/closing execution mode is being executed when the opening/closing execution mode is started, and indicates that the opening/closing execution mode is being executed when the opening/closing execution mode is ended. The information is erased from the storage area. The information in the storage area is stored and retained when the backup power is supplied to the work area 221 for specific control even if the supply of the operating power to the main CPU 63 is stopped, and the operation to the main CPU 63 is performed. When the first RAM clearing process and the second RAM clearing process are not executed when the power supply is restarted, they are stored and held.

If the last stop of the supply of operating power is neither during the game times nor during the execution of the opening/closing execution mode (step SD504 and step SD505: NO), the first display shake for special drawing from the main ROM 64 The minute table 391 is read (step SD506). Then, a lottery process for initial display data for special drawings is executed (step SD507). In the lottery process for initial display data for special maps, the current numerical information of the initial display counter 381 for special maps is acquired. Then, by collating the acquired numerical information with the first display distribution table 391 for special figures read out from the main ROM 64 in step SD506, the display data to be displayed this time is displayed for special figures. The first initial display data, the special initial drawing second initial display data, and the special special drawing third initial display data are selected.

The display data selected in the lottery process of the initial display data for special drawings is set in the first display data buffer 271 (step SD508). By controlling the display of the special figure display unit 37a using the display data stored in the first display data buffer 271, an initial display corresponding to the display data is performed on the special figure display unit 37a. That is, when the first initial display data for special drawing is set in the first display data buffer 271, the first initial display for special drawing is performed on the special drawing display portion 37a, and the first display data buffer 271 is displayed. If the second initial display data for special drawing is set to the special drawing, the second initial display for special drawing is performed in the special drawing display portion 37a, and the third initial for special drawing is displayed in the first display data buffer 271. When the display data is set, the special initial display 37a displays the third initial display for special drawings.

On the other hand, if the previous stop of the supply of operating power was either during the game times or during the open/close execution mode (step SD504 or step SD505: YES), the initial display data for special maps is Since it is not set in the 1 display data buffer 271, the display data stored before the supply of the operating power is stopped remains in the first display data buffer 271. Therefore, when the display on the special figure display unit 37a is started, the display content of the special figure display unit 37a immediately before the supply of the operating power is stopped is restarted as it is.

When the affirmative judgment is made in step SD504, the affirmative judgment is made in step SD505, or the process of step SD508 is executed, the fluctuation of the general figure display portion 38a in the clear target area 371 of the work area 221 for the specific control. By referring to the storage area in which the information indicating whether or not it is being displayed is stored, the supply of the operating power is resumed after the supply of the operating power is stopped during the variable display of the pattern on the normal figure display portion 38a. It is determined whether or not it is the situation (step SD509). The storage area stores information indicating that the variable display of the picture is being performed on the universal figure display section 38a when the variable display of the pattern is started on the universal figure display section 38a. When the variable display of the pattern is terminated at, the information indicating that the variable display of the pattern is being executed is erased from the storage area on the public figure display portion 38a. The information in the storage area is stored and retained when the backup power is supplied to the work area 221 for specific control even if the supply of the operating power to the main CPU 63 is stopped, and the operation to the main CPU 63 is performed. When the first RAM clearing process and the second RAM clearing process are not executed when the power supply is restarted, they are stored and held.

Further, by referring to the storage area in the clear target area 371 of the work area 221 for specific control that stores information indicating whether or not the normal power open state is being executed, the normal power open state is being executed. It is determined whether or not the supply of the operating power is resumed after the supply of the operating power is stopped (step SD510). Information indicating that the universal power open state is being executed is stored in the storage area when the universal power open state is started, and the universal power open state is being executed when the universal power open state is ended. The information indicating that there is is erased from the storage area. The information in the storage area is stored and retained when the backup power is supplied to the work area 221 for specific control even if the supply of the operating power to the main CPU 63 is stopped, and the operation to the main CPU 63 is performed. When the first RAM clearing process and the second RAM clearing process are not executed when the power supply is restarted, they are stored and held.

If the previous stoppage of the supply of operating power was neither during the variable display of the picture on the universal graphic display section 38a nor during the universal power open state (step SD509 and step SD510: NO), the main ROM 64 Then, the first display distribution table 393 for normal drawing is read from (step SD511). Then, the lottery process of the initial display data for universal graphics is executed (step SD512). In the lottery process for initial display data for a general figure, the current numerical value information of the initial display counter 382 for a general figure is acquired. Then, by collating the acquired numerical information with the first display sorting table 393 for general figures read from the main ROM 64 in step SD511, the display data to be displayed this time is displayed for general figures. Select from the first initial display data, the second initial display data for general drawings, and the third initial display data for general drawings.

The display data selected in the lottery process of the initial display data for general drawings is set in the third display data buffer 273 (step SD513). By controlling the display of the public figure display unit 38a using the display data stored in the third display data buffer 273, the general figure display unit 38a performs the initial display corresponding to the display data. That is, when the first initial display data for a general figure is set in the third display data buffer 273, the first initial display for a general figure is performed on the general figure display section 38a, and the third display data buffer 273 is displayed. If the second initial display data for a public figure is set in the, the second initial display for a general figure is performed in the general figure display unit 38a, and the third initial for a general figure is displayed in the third display data buffer 273. When the display data is set, the third figure display for a figure is performed on the figure display portion 38a.

On the other hand, if the last time the supply of operating power was stopped was during execution of variable display of the picture on the universal graphic display unit 38a or during execution of the universal power open state (step SD509 or step SD510: YES), Since the initial display data for general use is not set in the third display data buffer 273, the display data stored before the supply of the operating power is stored in the third display data buffer 273 as it is. .. Therefore, when the display on the public figure display unit 38a is started, the display content of the public figure display unit 38a immediately before the supply of the operating power is stopped is restarted as it is.

When the process of step SD503 is executed, the affirmative judgment is made in step SD509, the affirmative judgment is made in step SD510, or the process of step SD513 is executed, the clear target area of the work area 221 for specific control is executed. "1" is set to the display start flag provided in 371 (step SD514). The display start flag mainly determines whether or not the display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure reservation display unit 38a, and the general figure reservation display unit 38b should be started, as in the case of the 55th embodiment. This is a flag for specifying by the side CPU 63. When the value of the display start flag is "0", the main CPU 63 does not perform display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b. When the display start flag is set to "1", the main CPU 63 starts the display control of the special figure display section 37a, the special figure reservation display section 37b, the general figure display section 38a and the general figure reservation display section 38b.

Similar to the 55th embodiment, the display start flag is cleared to "0" in step SC204 of the main process (FIG. 185). The processing timing is after the supply of the operating power to the main CPU 63 is started, the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, the general figure reservation display unit 38b, and the first to fourth sections. The timing is earlier than the timing at which the second timer interrupt process (FIG. 188) for executing the display control of the notification display devices 201 to 204 is first executed. Then, in the display start process (FIG. 202) executed after the process at the start of supplying the operating power (step SC201 to step SC223) is completed, “1” is set to the display start flag. As a result, immediately after the supply of the operating power is resumed, the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b are maintained in the off state, and the supply of the operating power is performed. After the processing at the start (step SC201 to step SC223) is completed, the display control of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, and the general figure reservation display unit 38b is started.

In particular, in the display start process (FIG. 202), as already described, even in the situation where neither the first RAM clear process nor the second RAM clear process is executed in the main process (FIG. 185), the first display data buffer 271 is stored. The initial display data for special figures may be set and the initial display data for general figures may be set in the third display data buffer 273. In this case, if the display control of the special figure display unit 37a and the general figure display unit 38a is started immediately after the supply of the operating power to the main CPU 63 is started, the special figure display unit 37a and the general figure display unit are displayed. In 38a, the initial display will be started immediately after the display content immediately before the supply of the operating power is stopped is displayed. On the other hand, when display data is set in the first display data buffer 271 and the third display data buffer 273 in the display start process (FIG. 208), the display start flag is set after the process of setting the display data ends. Is set to "1" and display of the special figure display portion 37a and the general figure display portion 38a is started. This makes it possible to prevent the display contents from changing as described above.

According to the above configuration, even if the first RAM clearing process and the second RAM clearing process of the set value updating process are not executed in the process (step SC201 to step SC223) at the start of supplying the operating power, the operating power is supplied. When the stopped situation is neither during the execution of the game times nor during the execution of the opening/closing execution mode, when the display is started on the special figure display section 37a, the initial is set on the special figure display section 37a. The display starts. Even if the first RAM clearing process and the second RAM clearing process of the set value updating process are not executed in the process at the start of supplying the operating power (step SC201 to step SC223), the supply of the operating power is stopped. When the display is started on the public figure display unit 38a in the case where the display is not being executed on the general figure display unit 38a while the variable display of the pattern is being executed or the general electric open state is being executed. Initial display is started in the section 38a. Then, as described above, even when the first RAM clearing process or the second RAM clearing process of the set value updating process is executed in the process (step SC201 to step SC223) at the time of starting the supply of the operating power, the special figure display unit 37a and Initial display is carried out on the universal figure display section 38a. Accordingly, even if it is confirmed that the initial display is performed on the special figure display unit 37a and the general figure display unit 38a when the supply of the operating power is started, the first RAM clear processing and the second RAM clear processing are performed. It becomes possible not to specify that any one has been executed.

In addition, when the initial display is performed on the special figure display unit 37a and the general figure display unit 38a when the first RAM clear process and the second RAM clear process of the set value update process are not executed, the special figure is drawn during the lottery process of the initial display data. The first display allocation table 391 for general purpose and the first display allocation table 393 for general purpose are referred to. As a result, only when the set value update process (FIG. 205) is executed and a set value that is equal to or greater than the advantage of the set values up to then is newly set, the special display is used for the lottery process of the initial display data. It is possible to refer to the second display allocation table 392 and the second display allocation table 394 for general purpose. Therefore, even if the configuration is such that it is not possible to specify that either the first RAM clearing process or the second RAM clearing process has been executed as described above, the supply of operating power is started and the special figure display unit is displayed. By confirming the contents of the initial display when the display of 37a and the universal figure display section 38a is started, it is possible to predict to the player whether or not a new set value equal to or higher than the advantage of the set values up to that time is newly set. It becomes possible.

On the other hand, the situation in which the supply of operating power is stopped is either during execution of the game times or during execution of the opening/closing execution mode, and the first RAM in the process (step SC201 to step SC223) at the time of starting the supply of operating power. If the clearing process and the second RAM clearing process are not executed, when the display is started on the special figure display unit 37a, the special figure display unit has the display content just before the supply of the operating power is stopped. The display of 37a is controlled. In addition, when the supply of the operating power is stopped is either the execution of the variable display of the picture on the universal display unit 38a or the execution of the universal power open state, the process at the start of the supply of the operating power (step SC201). ~ If the first RAM clearing process and the second RAM clearing process are not executed in step SC223), the display content immediately before the supply of the operating power is stopped when the display is started on the universal figure display unit 38a The general figure display unit 38a is display-controlled so that As a result, when the game situation immediately before the supply of the operation power is stopped is resumed when the supply of the operation power is resumed, the special figure display unit 37a and the normal state are displayed in a mode corresponding to the restart of the game situation. It becomes possible to start the display on the diagram display unit 38a.

<64th Embodiment>
In the present embodiment, the execution contents of the game are different from those in the 56th embodiment. The configuration different from that of the 56th embodiment will be described below. The description of the same configuration as the 56th embodiment is basically omitted.

FIG. 209 is a front view of the game board 24 in the present embodiment.

An inner rail portion 401 and an outer rail portion 402 are attached to the game board 24 so as to partition a part of the outer edge of the game area PA, and the inner rail portion 401 and the outer rail portion 402 guide means. The guide rail is configured as. The game ball launched from the game ball launch mechanism 27 (see FIG. 2) is guided to the upper part of the game area PA by the guide rail.

The game board 24 is formed with a plurality of large and small openings penetrating in the front-rear direction. In each opening, a general winning portion 411, a first operating portion 412, a second operating portion 413, a through winning portion 414, a distribution winning device 415, a special electricity winning device 416, a variable display unit 421, a special drawing unit 422 and a universal drawing. Units 423 and the like are provided respectively. A total of four general winning portions 411 are provided, and one is provided for each other.

Even if a game ball enters the through winning portion 414, the game ball is not paid out. On the other hand, when a game ball is thrown into any of the general winning portion 411, the first operating portion 412, the second operating portion 413, the distribution winning device 415, and the special electric winning device 416, it can be used by the player. A predetermined number of game balls are paid out in order to increase the number of game media. Regarding the number of prize balls, specifically, when the game balls enter the general prize unit 411, 10 game balls are paid out, and the game balls enter the first operation unit 412. When the game ball is paid out, three game balls are paid out, and when the game ball is put into the second operating unit 413, one game ball is paid out, and the distribution winning device is executed. When a game ball enters 415, a payout of 15 game balls is executed, and when a game ball enters the special electric prize winning device 416, a sort prize winning device 415 enters. The same 15 game balls as when the balls are generated are paid out.

As will be described later, the distribution prize device 415 is provided with a discharge passage region 445b and a V prize passage region 445c, and the game balls that have entered the distribution prize device 415 are the discharge passage region 445b and the V prize passage. Although it will pass any of the areas 445c, the same number (specifically 15) of game balls are paid out regardless of which of the discharge passage area 445b and the V winning passage area 445c the game balls pass. To be done. Further, the number of prize balls is arbitrary, and for example, the number of prize balls of the first actuation unit 412 and the second actuation unit 413 may be the same, and the number of prize balls of the distribution winning apparatus 415 is the special prize winning. The configuration may be larger or smaller than the number of prize balls of the device 416.

In addition, an out port 24a is provided at the bottom of the game board 24, and game balls that have not entered various winning ports are discharged from the game area PA through the out port 24a. Further, the game board 24 is provided with a large number of nails 24b for appropriately dispersing and adjusting the falling direction of the game balls, and various members such as a wind turbine.

The variable display unit 421 is provided so as to include the central portion of the game area PA. Due to the peripheral portion of the variable display unit 421 protruding toward the front of the pachinko machine 10 from the surface of the game board 24, a region where the game balls shot in the game region PA can flow is defined. Specifically, in the game area PA, an upper area PA1 that is an area above a predetermined height position of the variable display unit 421, and below the upper area PA1 continuously below the upper area PA1 than the variable display unit 421. A left side area PA2, which is a left side area, and a right side area PA3, which is an area that is continuous below the upper side area PA1 and is on the right side of the variable display unit 421, and a left side area PA2 and a right side area PA3, respectively. On the other hand, a lower area PA4 that is an area below the variable display unit 421 that is continuous below the area is partitioned.

As the player operates the firing operation device 28 with a rotation amount in a first range that is less than the reference rotation amount as the first firing operation, the game ball is left in the upper area PA1 to the left of the lateral center position. Let it flow down. In this case, the game balls flow down in the order of the upper area PA1, the left area PA2, and the lower area PA4. On the other hand, the player operates the firing operation device 28 as the second firing operation with the rotation amount in the second range that is equal to or greater than the reference rotation amount, so that the player operates rightward of the lateral center position in the upper area PA1. The game ball begins to flow down. In this case, the game balls flow down in the order of the upper area PA1, the right area PA3, and the lower area PA4. That is, the player can play the game ball so that the game ball flows down the left side area PA2 of the left side area PA2 and the right side area PA3 by adjusting the turning operation amount of the firing operation device 28, and the right side area. The game can be played so that the game ball flows down the PA3. By the way, when the firing operation device 28 is operated with the maximum rotation amount, the game balls flow down in the order of the upper area PA1→the right area PA3→the lower area PA4.

The first operating unit 412 is installed in the lower area PA4. The first actuating portion 412 is opened upward, and a member such as an opening/closing member for preventing the game ball from entering the first actuating portion 412 is not provided. Then, in a situation where the game balls are being fired in the same manner, the winning probability to the first actuation unit 412 is constant regardless of the game state. In other words, the first operating portion 412 can always enter the game ball flowing down the game area PA toward the first operating portion 412. Further, the first actuating portion 412 is arranged directly below the stage 421a formed in the variable display unit 421, and is a game ball that has flown onto the stage 421a via the guide passage formed in the variable display unit 421. The game balls discharged from the lateral center of the stage 421a to the outside of the variable display unit 421 are easy to win in the first operating portion 412. The first operating unit 412 is provided with a detection sensor 412a, and the detection sensor 412a detects a game ball that has won the first operating unit 412. The detection sensor 412a is electrically connected to the MPU 62 of the main control device 60, and based on the detection result of the detection sensor 412a, the main CPU 63 determines whether or not there is a winning in the first operating unit 412.

As described above, the first operating portion 412 is provided in the lower area PA4, but the game ball that has flowed down the right side area PA3 is on the upstream side toward the right side area PA3 with respect to the first operating portion 412. The restriction nail 24c is provided so that the first operating portion 412 cannot be reached. Further, the entrance of the guide passage to the stage 421a is provided for the left side area PA2, but not for the right side area PA3. With these configurations, when the firing operation device 28 is operated so that the game balls flow down the left side area PA2, winning to the first actuating portion 412 is possible, but the game balls flow down the right side area PA3. If the firing operation device 28 is operated as described above, winning of the first operating unit 412 is not possible. However, the present invention is not limited to this, and the restriction nail 24c is not provided or the entrance of the guide passage to the stage 421a is provided in the right side area PA3, so that the game ball flows down the right side area PA3. Even when the firing operation device 28 is being operated, the first operating portion 412 may be awarded.

The second operating unit 413 is installed in the right side area PA3. That is, the second operating unit 413 cannot win when the firing operating device 28 is operated so that the game ball flows down the left side area PA2, and the winning operation is performed so that the game ball flows down the right side area PA3. When the device 28 is operated, winning is possible.

The configuration of the second operating unit 413 will be described with reference to FIG. FIG. 210(a) is a vertical cross-sectional view of the second operating portion 413 in the non-guided state. The second operating unit 413 includes a base unit 431 in which a discharge passage 433 for discharging the game balls flowing from the game area PA to the rear of the game board 24 is formed, and a discharge ball 433 for discharging the game balls flowing down the game area PA. And a guiding unit 432 for guiding to. The inlet portion 433a of the discharge passage 433 has an opening area equal to or larger than one gaming ball and is open toward the front of the pachinko machine 10. A detection sensor 434 is provided on the outlet 433b side of the discharge passage 433, and the detection sensor 434 detects a game ball that has won a prize in the second operating unit 413. The detection sensor 434 is electrically connected to the MPU 62 of the main control device 60, and based on the detection result of the detection sensor 434, the main CPU 63 determines whether or not there is a win in the second operation unit 413.

The guiding unit 432 receives a game ball flowing down from the front area of the entrance portion 433a in the game area PA from below, and guides the received game ball into the discharge passage 433 and into the discharge passage 433. Situation in which the guide driving unit 436 for displacing the guide member 435 between the initial position where the guiding of the game ball is impossible and the guiding position where the guiding is possible, and the guide member 435 are arranged in the initial position. In the situation where the guide member 435 is arranged in the blocking position for blocking the inflow of the game ball into the discharge passage 433 and is arranged in the guide position, the guide member 435 is arranged in the non-blocking position that does not block the flow of the game ball in the discharge passage 433. And a blocking member 437. The guide member 435 and the blocking member 437 are arranged so as to face each other with a predetermined gap in the vertical direction such that the guide member 435 faces downward. A transmission unit 438 is provided to transmit the driving force of the guide driving portion 436 to the guide member 435 and the blocking member 437.

When the guide driving unit 436 is in the non-driving state, the guide member 435 is arranged at the initial position and the blocking member 437 is arranged at the blocking position by the biasing force of the biasing means such as a spring (not shown). In this case, the guide member 435 and the blocking member 437 are entirely buried in the discharge passage 433 and do not project into the game area PA. As a result, the game ball flowing down the front area of the inlet 433a of the discharge passage 433 in the game area PA is not guided into the discharge passage 433 by the guide member 435 and the blocking member 437, that is, the game ball is the second. The game area PA flows downward without entering the operation portion 413. Further, since the blocking member 437 is arranged at the blocking position, the substantial opening area of the inlet portion 433a of the discharge passage 433 is less than one game ball. As a result, in the situation where the guide member 435 is arranged at the initial position, it is possible to reliably prevent the game ball from entering the second operation portion 413.

When the guide drive portion 436 is driven, the guide member 435 and the blocking member 437 are displaced against the biasing force of the biasing means, the guide member 435 is arranged at the guide position, and the blocking member 437 is not moved. It is placed in the blocking position. FIG. 210(b) is a vertical cross-sectional view of the second operating portion 413 in the guided state.

When the guide member 435 is arranged at the guide position, the tip end side of the guide member 435 projects from the inlet portion 433a of the discharge passage 433 to the game area PA side. This protrusion amount is such that a game ball flowing down in the front area of the entrance portion 433a in the game area PA can be received from below. The upper end of the guide member 435 is inclined downward toward the inlet portion 433a of the discharge passage 433, so that the game ball received from below on the front end of the guide member 435 is not a guide ball of the guide member 435. It rolls on the upper surface and is guided into the discharge passage 433. Further, when the blocking member 437 is arranged at the non-blocking position, the blocking member 437 is displaced so that its tip end is located above the blocking position, so that the game is rolled on the upper surface of the guide member 435. The balls flow into the discharge passage 433 without interfering with the blocking member 437. As a result, the guide drive unit 436 is brought into a driven state, and thus the game ball flowing down in the front area of the entrance section 433a in the game area PA enters the second operation section 413. Hereinafter, for convenience of description, a state in which the guide driving unit 436 is in the non-driving state, the guide member 435 is in the initial position, and the blocking member 437 is in the blocking position is the non-guided state of the guiding unit 432 or the second operating unit. A state in which the guide driving unit 436 is in a driving state, the guide member 435 is arranged in the guiding position, and the blocking member 437 is arranged in the non-blocking position is referred to as a closed state of the guiding unit 432 or the second operating unit. It is called an open state of 413.

The second operating portion 413 includes a cover member 439 provided so as to face the inlet portion 433 a of the discharge passage 433 from the front of the pachinko machine 10. The cover member 439 is formed in a gate shape so as to form a vertical passage portion 439a in the front area of the entrance portion 433a in the game area PA, and a game ball that passes through the front area of the entrance portion 433a at the same time. It is provided so as to limit the movement to the front and the lateral movement of the game ball to the front of the pachinko machine 10 while limiting the number to the individual pieces. This prevents a plurality of game balls from being simultaneously guided into the discharge passage 433 of the second operating unit 413 when the guiding unit 432 of the second operating unit 413 is in the guided state, and In the guided state, it becomes possible to reliably guide the game ball passing through the front area of the inlet portion 433a into the discharge passage 433. The guide drive unit 436 is electrically connected to the MPU 62 of the main controller 60, and the drive control of the guide drive unit 436 is executed by the main CPU 63.

As shown in FIG. 209, a through winning portion 414 is provided above the second operating portion 413 in the right side area PA3. In other words, the through winning portion 414 cannot win the prize when the firing operating device 28 is operated so that the game ball flows down the left side area PA2, and the firing operating device is controlled so that the game ball flows down the right side area PA3. When 28 is operated, winning is possible. The through winning portion 414 has a through hole that penetrates in the vertical direction. In addition, a second actuating portion 413 is provided at a position vertically below the through winning prize portion 414, and further, in the right side area PA3, on the downstream side of the second actuating portion 413, the special electric prize winning device 416 and the distribution winning device. 415 is provided. Therefore, it is possible for the game balls that have won the through winning portion 414 to win the second operating portion 413, the special electric winning device 416 or the distribution winning device 415.

The right side area PA3 where the second actuating section 413 and the through winning section 414 are collectively arranged is defined by the side wall 421b which bulges toward the front of the pachinko machine 10 relative to the board surface of the game board 24 in the variable display unit 421 on the left side. At the same time, the right side is defined by a restriction wall provided on the resin base 21 of the inner frame 13 and protruding toward the front of the pachinko machine 10 from the board surface of the game board 24. The right side area PA3 is set to have a smaller lateral dimension than the lower area PA4, and the lateral dimension is such that it is impossible to arrange the game ball entry devices in the lateral direction at the same height position. Has become. As a result, it becomes possible to limit the flow path of the game ball flowing down the right side area PA3 to a predetermined range, and it is easy for the game ball to enter the second actuating part 413 and the through winning part 414. ..

The arrangement mode of the plurality of nails 24b on the upstream side of the through winning portion 414 in the right area PA3 is set so as to guide the game balls flowing down the right area PA3 to the through winning portion 414. As a result, the game balls flowing down the right side area PA3 can easily enter the through winning part 414, and easily enter the through winning part 414 and easily enter the second operating part 413. There is. The through winning section 414 is provided with a detection sensor 414a, and the detection sensor 414a detects a game ball that has won the through winning section 414. The detection sensor 414a is electrically connected to the MPU 62 of the main control device 60, and based on the detection result of the detection sensor 414a, the main CPU 63 determines whether or not there is a prize in the through winning part 414.

Based on the winning of the through winning part 414, the guiding unit 432 of the second operating part 413 is switched from the non-guided state to the guided state. Specifically, an internal lottery is performed with the winning of the through winning portion 414 as a trigger, and the public figure display portion of the public figure unit 423 provided in the lower left corner of the game area PA where the game ball does not pass. The variable display of the pattern is performed at 423a. Then, when the result of the internal lottery is the winning of the guidance execution state, the stop result corresponding to the result is displayed, and the variable display of the pattern on the universal figure display unit 423a is finished, the process shifts to the guidance execution state. In the guidance execution state, the guidance unit 432 enters the guidance state in a predetermined mode.

The universal figure display unit 423a is configured by a segment display unit in which a plurality of segment light emitting units are arranged in a predetermined manner. In this case, it is impossible to perform a complicated display like the symbol display device 424 on the universal figure display unit 423a, but it is possible to reduce the processing load for controlling the display of the universal figure display unit 423a. However, the present invention is not limited to this, and the liquid crystal display device may be composed of a liquid crystal display device, an organic EL display device, a CRT, a dot matrix display device, or another type of display device. Further, as the pattern displayed on the public figure display unit 423a, a configuration in which a plurality of types of characters are displayed, a configuration in which a plurality of types of symbols are displayed, a configuration in which a plurality of types of characters are displayed, or a plurality of types of colors A configuration in which is displayed is conceivable.

In the universal figure unit 423, a universal figure hold display section 423b is provided at a position adjacent to the universal figure display section 423a. The maximum number of game balls that have won in the through winning section 414 is reserved, and the reserved number is displayed by lighting the universal figure reservation display section 423b. The public figure display unit 423a and the public figure hold display unit 423b are electrically connected to the MPU 62 of the main controller 60, and the main CPU 63 executes display control of the public figure display unit 423a and the public figure hold display unit 423b. To be done.

By the way, the display range of the universal figure display unit 423a is narrower than the display surface of the symbol display device 424. Furthermore, the display range for both the public figure display portion 423a and the public figure hold display portion 423b is also narrower than the display surface of the symbol display device 424. Thereby, it becomes possible to raise the player's attention to the symbol display device 424 more than the public figure display unit 423a and the public figure hold display unit 423b.

In this pachinko machine 10, a plurality of types of modes are set as support modes so that the frequency of occurrence of the guidance state of the guidance unit 432 is different. Specifically, in the support mode, the frequency with which the guiding unit 432 is in the guiding state per unit time is relative when compared in a situation in which the game balls are continuously emitted in the same manner with respect to the gaming area PA. The high-frequency support mode and the low-frequency support mode are set so as to be high and low.

The high-frequency support mode and the low-frequency support mode have the same probability (specifically, 4/5) that they will be in the guided state in the guided state lottery based on the entry of the game ball into the through winning portion 414. However, in the high frequency support mode, the number of times that the guidance unit 432 is in the guidance state when the guidance state is won is set to a greater number than in the low frequency support mode, and guidance is performed in one guidance control execution time. The upper limit guidance period for which the unit 432 is maintained in the guidance state is set to be long. In this case, when the guiding state is won in the high frequency support mode and the guiding state of the guiding unit 432 occurs a plurality of times, the closing period from the end of one guiding state to the start of the next guiding state is It is set shorter than one upper limit induction period. Furthermore, the high-frequency support mode is more secure than the low-frequency support mode, since the guidance state lottery is performed once and then the next guidance state lottery is performed. The display continuation time of one variation display of the picture in 423a) is set to be short.

As described above, in the high frequency support mode, the probability of winning the second operating unit 413 is higher than in the low frequency support mode. In other words, in the low frequency support mode, the probability of winning the first operating portion 412 is higher than in the second operating portion 413, but in the high frequency support mode, the second operating portion 412 is operated more frequently than the first operating portion 412. The probability of winning a prize in the section 413 increases. Then, when a prize is generated in the second operating unit 413, a predetermined number of game balls are paid out, so in the high frequency support mode, the player plays the game while not reducing the number of balls he/she holds. You can

The configuration for increasing the frequency of the high-frequency support mode to be in the guiding state per unit time higher than that of the low-frequency support mode is not limited to the above, and for example, the guiding state winning in the guiding state lottery. It may be configured to increase the probability that In addition, a securing time that is secured when the next guidance state lottery is performed after one guidance state lottery is performed (for example, is executed in the universal figure display unit 423a based on the winning of the through winning unit 414). In a configuration in which multiple types of (variable display time) are prepared, even in the high-frequency support mode, a shorter securing time can be selected more easily than in the low-frequency support mode, or even if the average securing time is set shorter. Good. Furthermore, the number of executions of the guidance state is increased, the upper limit guidance period is lengthened, and the securing time secured when one guidance state lottery is performed after one guidance state lottery is shortened, Even if the advantage of the high-frequency support mode over the low-frequency support mode is increased by applying any one condition or a condition of any combination of shortening the average time of securing time and increasing the winning probability. Good.

A winning lottery is carried out based on the occurrence of a prize in the first operating unit 412 or the second operating unit 413. When the winning lottery is carried out, the special figure unit 422 displays the variation of the design, and finally the result corresponding to the result of the winning lottery is displayed.

The special figure unit 422 is provided at a lower right corner of the game area PA and at a position where the game ball does not flow forward. Further, the special drawing unit 422 is provided at a position visible from the front of the pachinko machine 10 through the window panel 52 even when the front door frame 14 is arranged at the closed position. Therefore, the manager of the game hall can visually check the display contents of the various display units 425 to 429 provided in the special figure unit 422 without requiring the opening operation of the gaming machine main body 12 and the opening operation of the front door frame 14. Becomes

FIG. 209( b) is an explanatory diagram for explaining the special drawing unit 422. More specifically, the special figure unit 422 is provided with a first special figure display section 425 and a second special figure display section 426. In the first special map display unit 425, the winning lottery is performed on the basis of the occurrence of the winning in the first operating unit 412, and the variable display of the pattern is performed, and finally the result corresponding to the lottery result is displayed. To be done. In addition, in the second special figure display unit 426, the winning lottery is performed based on the occurrence of the winning in the second actuating unit 413, the variable display of the pattern is performed, and the result corresponding to the lottery result is finally obtained. Is displayed. The variation display of the picture pattern is started by either the first special figure display unit 425 or the second special figure display unit 426, and the variable display of the picture pattern displays a predetermined result and ends until the game time is 1 Equivalent to times.

The first special figure display portion 425 includes seven display segments 425a. Each of these display segments 425a is formed in a rod shape and has a light emitting body such as an LED inside. The seven display segments 425a are arranged such that the first special figure display portion 425 is a so-called 7-segment display. The first special figure display unit 425 is electrically connected to the MPU 62 of the main control device 60, and the main CPU 63 individually controls turning on and off of each display segment 425a. It is impossible to perform a complicated display like the symbol display device 424 on the first special figure display unit 425, but it is possible to reduce the processing load for controlling the display of the first special figure display unit 425. ..

The display segments 425a may be formed in a circular shape, and the display segments 425a may be arranged in a linear shape or a circular shape. In addition, the first special figure display unit 425 may be configured by a liquid crystal display device, an organic EL display device, a CRT, a dot matrix display device, or another type of display device. Further, as the pattern displayed on the first special figure display unit 425, a plurality of types of characters are displayed, a plurality of types of symbols are displayed, a plurality of types of characters are displayed, or a plurality of types are displayed. A configuration in which the color of is displayed is conceivable.

The second special figure display portion 426 includes seven display segments 426a. Each of these display segments 426a is formed in a rod shape and has a light emitting body such as an LED inside. These seven display segments 426a are arranged such that the second special figure display portion 426 is a so-called 7-segment display. The second special figure display unit 426 is electrically connected to the MPU 62 of the main control device 60, and the main CPU 63 individually controls turning on and off of each display segment 426a. It is impossible to perform a complicated display like the symbol display device 424 on the second special figure display unit 426, but it is possible to reduce the processing load for display control of the second special figure display unit 426. ..

The display segments 426a may be formed in a circular shape, and the display segments 426a may be arranged in a linear shape or a circular shape. In addition, the second special figure display unit 426 may be configured by a liquid crystal display device, an organic EL display device, a CRT, a dot matrix display device, or another type of display device. As the picture displayed on the second special figure display unit 426, a plurality of types of characters are displayed, a plurality of types of symbols are displayed, a plurality of types of characters are displayed, or a plurality of types are displayed. A configuration in which the color of is displayed is conceivable.

In the special figure unit 422, a first special figure reservation display section 427 is provided at a position adjacent to the first special figure display section 425. The maximum number of game balls that have won in the first operating unit 412 is four, and the number of the reserved balls is displayed by turning on the first special figure reservation display unit 427. A second special figure reservation display section 428 is provided at a position adjacent to the second special figure display section 426. The number of game balls that have won in the second operating unit 413 is reserved up to a maximum of four, and the reserved number is displayed by turning on the second special figure reservation display unit 428. The first special figure reservation display section 427 and the second special figure reservation display section 428 are electrically connected to the MPU 62 of the main control device 60, and the main CPU 63 causes the first special figure reservation display section 427 and the second special figure. The display control of the hold display unit 428 is executed.

In the special figure unit 422, a special display section 429 is provided at a position adjacent to the second special figure display section 426. When the opening/closing execution mode in which the special electric prize winning device 416 is opened is started, the special display portion 429 is display-controlled so as to be in a predetermined display state, the opening/closing execution mode is ended, and a new game time is started. If so, the special display unit 429 is display-controlled so that the predetermined display state ends and the light is turned off.

The special display portion 429 includes seven display segments 429a. Each of these display segments 429a is formed in a rod shape and has a light emitting body such as an LED inside. These seven display segments 429a are arranged so that the special display portion 429 is a so-called 7-segment display. The special display unit 429 is electrically connected to the MPU 62 of the main control device 60, and the main CPU 63 individually controls turning on and off of each display segment 429a. It is impossible to perform a complicated display like the symbol display device 424 on the special display unit 429, but it is possible to reduce the processing load for controlling the display of the special display unit 429.

The display segments 429a may be formed in a circular shape, and the display segments 429a may be arranged in a linear shape or a circular shape. Further, the special display unit 429 may be configured by a liquid crystal display device, an organic EL display device, a CRT, a dot matrix display device, or another type of display device. The contents displayed on the special display unit 429 include a configuration in which a plurality of types of characters are displayed, a configuration in which a plurality of types of symbols are displayed, a configuration in which a plurality of types of characters are displayed, or a plurality of types of colors. The configuration that is displayed can be considered.

The display range of the first special figure display unit 425 and the second special figure display unit 426 is narrower than the display surface of the symbol display device 424. Further, the display range of the entire first special figure display unit 425, the second special figure display unit 426, the first special figure reservation display unit 427, the second special figure reservation display unit 428 and the special display unit 429, the symbol display The area is narrower than the display surface of the device 424. Thereby, the game to the symbol display device 424 than the first special figure display unit 425, the second special figure display unit 426, the first special figure reservation display unit 427, the second special figure reservation display unit 428 and the special display unit 429. It is possible to increase the attention of the person.

When the variable display of the pattern is performed on the first special figure display portion 425 or the second special figure display portion 426, that is, when the game time is being executed, it is adjusted in the symbol display device 424 provided in the variable display unit 421. Display effect is performed. In addition, in the symbol display device 424, not only the display effect triggered by the winning of the first operating unit 412 or the second operating unit 413, but also the display effect in the opening/closing execution mode which is shifted after the jackpot result is obtained and the like. A display effect or the like during the distribution execution mode, which shifts after the result of the small hit, is performed. Further, in the opening/closing execution mode, the distribution execution mode, and the high frequency support mode, a right hitting notification image for notifying that the game ball should be launched aiming at the right side area PA3 is displayed on the symbol display device 424. ..

The symbol display device 424 is configured as a liquid crystal display device including a liquid crystal display, and the display content is controlled by the display control device 82. The symbol display device 424 is not limited to the liquid crystal display device, and may be another display device having a display surface such as a plasma display device, an organic EL display device or a CRT, and is a dot matrix display device. May be.

The contents of the display effect performed by the symbol display device 424 during the execution of the game will be described with reference to FIG. FIG. 211 is an explanatory diagram for explaining display contents of the symbol display device 424 when the game times are executed.

As shown in FIG. 211(a), on the display surface of the symbol display device 424, three symbol rows Z1, Z2, Z3 of the upper stage, the middle stage and the lower stage are set as a plurality of display areas. Each of the symbol rows Z1 to Z3 is configured by arranging a main symbol and a sub symbol in a predetermined order. That is, when the game times are executed, the variable display of the symbols is performed using the entire display surface of the symbol display device 424.

212 is an explanatory diagram for explaining the main symbol and the sub symbol that are variably displayed in each of the symbol columns Z1 to Z3. As shown in FIGS. 212(a) to 212(j), the symbols, which are a kind of the symbols, are nine types of main symbols to which the numbers "1" to "9" are respectively attached and shell-shaped symbols. And a sub-pattern consisting of. More specifically, the numbers of "1" to "9" are respectively attached to nine types of character designs such as octopus to constitute the main design.

As shown in FIG. 211(b), in the upper symbol row Z1, nine kinds of main symbols “1” to “9” are arranged in descending order of numbers, and a sub symbol is 1 between each main symbol. They are arranged one by one. In the lower symbol row Z3, nine types of main symbols “1” to “9” are arranged in ascending order of numbers, and one sub symbol is arranged between each main symbol. That is, the upper symbol row Z1 and the lower symbol row Z3 are composed of 18 symbols. On the other hand, in the middle symbol row Z2, nine types of main symbols "1" to "9" are arranged in ascending order of numbers, and then between the main symbol "9" and the main symbol "1". The main symbols of "4" are additionally arranged, and one sub-symbol is arranged between these main symbols. That is, only in the middle symbol row Z2, 10 main symbols are arranged and configured by 20 symbols. Then, on the display surface, the symbols in each of the symbol columns Z1 to Z3 are variably displayed so as to scroll in a predetermined direction with periodicity. The symbol display device 424 is configured such that three symbols are stopped and displayed for each of the symbol columns Z1 to Z3, and as a result, a total of 9 symbols of 3×3 are stopped and displayed. Further, as shown in FIG. 211(a), five effective lines, that is, a left line L1, a middle line L2, a right line L3, a right downward line L4, and a right upward line L5 are set in the symbol display device 424. ..

When the variable display of the symbols is performed on the display surface based on the winning of the first operating unit 412 or the second operating unit 413, the symbols of each of the symbol columns Z1 to Z3 are scrolled in a predetermined direction with periodicity. The variable display starts at. Then, basically, the variable display is switched to the standby display in the order of the upper symbol row Z1, the lower symbol row Z3, and the middle symbol row Z2, and finally the predetermined symbol is statically displayed in each of the symbol rows Z1 to Z3. Is ended by. Further, when the variable display of the symbols ends, if the result of the internal lottery is the 15R jackpot result described later, a combination of "7" symbols is formed on any of the activated lines, and the result of the internal lottery will be described later. If it is a 6R jackpot result, a combination of the same odd symbols other than the “7” symbol is formed on any of the activated lines, and the result of the internal lottery is one of the first to third small jackpot results described later. If so, a combination of the same even symbols is formed on any of the activated lines.

In the configuration in which the variable display of the symbols is performed in each of the symbol columns Z1 to Z3 as described above, the expected effect is set as the display effect of the symbol display device 424 when the game times are executed. The expected effect is a display state for making the player think that it is a variable display state that is likely to be a jackpot result, in a stage before the variable display of the symbol on the symbol display device 424 is started and the stop result is derived and displayed. Say. Two types of expected effects are set: a reach display and a notice display for expecting a reach display or a jackpot result in a stage before the reach display occurs.

In the reach display, a combination of reach symbols is displayed by stopping and displaying the same type of symbols for the upper symbol column Z1 and the lower symbol column Z3 among the plural symbol columns Z1 to Z3, and the remaining middle symbols in that state A display state in which variable display of symbols is performed is included in the column Z2. Also, in the state where the reach symbol combination is displayed as described above, while performing the variable display of the symbols in the remaining symbol columns, the reach effect is displayed by displaying a predetermined character or the like as a moving image on the background screen. , A combination of reach patterns is displayed in a reduced size or hidden, and a reach effect is included by displaying a predetermined character or the like as a moving image on substantially the entire display surface. If it is a game time that is a big hit result or a small hit result, a symbol of the same type as the symbol forming the combination of reach symbols is stopped and displayed on the reach line in the middle symbol row Z2, and the jackpot result and the small hit result are displayed. If it is a game time that does not become any, a symbol different from the symbol forming the combination of reach symbols is stopped and displayed on the reach line in the middle symbol row Z2.

In the notice display, after the variable display of the symbols is started in each of the symbol columns Z1 to Z3, the symbols are variably displayed in all the symbol columns Z1 to Z3, or a part of the symbol columns Z1 to Z3. In a situation in which the symbols are variably displayed in Z3 and the plurality of symbol columns Z1 to Z3, a mode in which the character is displayed separately from the symbols on the symbol columns Z1 to Z3 is included. Further, the background screen may be a predetermined mode different from the previous modes, or the symbols on the symbol rows Z1 to Z3 may be a predetermined mode different from the previous modes. Such advance notice display can occur at both game times when the reach display is performed and when the reach display is not performed, but the reach display is higher than the case where the reach display is not performed. It is set to occur with a probability.

When either the 6R jackpot result or the 15R jackpot result is selected in the internal lottery executed based on the winning of the first operating portion 412 or the second operating portion 413, the game time corresponding to the jackpot result is finished. After that, the mode is changed to the open/close execution mode. In the opening/closing execution mode, it is possible to win the special electric prize winning device 416. As shown in FIG. 209, the special electric winning device 416 is provided at a position below the second operating portion 413 and above the distribution winning device 415 in the right area PA3. That is, the special electric prize winning device 416 cannot win the prize when the shooting operating device 28 is operated so that the game ball flows down the left side area PA2, and the shooting operating device is operated so that the game ball flows down the right side area PA3. When 28 is operated, winning is possible.

As shown in FIG. 209, the special electric winning device 416 includes a special winning opening 416a formed in a size that allows the game ball to pass therethrough, and the game ball cannot pass through the special winning port 416a. And a special electric side opening/closing member 416b for switching to an open state in which a game ball can pass. The special electric side opening/closing member 416b is opened by being driven by a special electric drive unit 416c through a link mechanism (not shown). The special electric winning device 416 is provided with a game ball passage such that the special winning opening 416a serves as an entrance portion, and the game ball flowing into the game ball passage through the special winning opening 416a is a special electric prize detection sensor provided in the game ball passage. After being detected by 416d, it is discharged to the rear of the game board 24. The special electric prize winning detection sensor 416d is electrically connected to the MPU 62 of the main control device 60, and the main CPU 63 determines whether or not there is a prize for the special electric prize winning device 416 based on the detection result of the special electric prize winning detection sensor 416d. Further, the special electric drive unit 416c is electrically connected to the MPU 62 of the main controller 60, and the main CPU 63 executes drive control of the special electric drive unit 416c.

In the opening/closing execution mode, a plurality of times (specifically, 5, 6, 8, 14 or 16 times) of the round game is executed. The round game is continued until either one of the conditions that the number of times of opening and closing the special electric prize winning device 416 becomes the upper limit number and that a predetermined upper limit winning number of game balls is won in the special electric prize winning device 416. It is a game to play. In this embodiment, the special electric prize winning device 416 is opened and closed once in one round game, and the open duration in each round game is set to 29 seconds. Further, the upper limit number of winnings to the special electric winning device 416 is set to 10. In the situation where the firing operation device 28 is operated by the player, the game ball firing mechanism 27 is drive-controlled so that one game ball is fired toward the game area PA in 0.6 seconds, so that a round game is performed. The opening continuation period of is set to a time longer than the product of the firing cycle of the game ball and the maximum winning number of one round game. Therefore, in each round game, it can be expected that the special electric prize winning device 416 will win the game balls of the upper limit number or more.

When any of the first small hit result to the third small hit result is selected in the internal lottery executed based on the winning of the second operating unit 413, after the game times corresponding to the small hit result are finished. Switch to distribution execution mode. In the distribution execution mode, it is possible to win the distribution winning device 415.

As shown in FIG. 209, the distribution winning device 415 is provided at a position below the special electric winning device 416 in the right area PA3. In other words, the distribution prize winning device 415 cannot win a prize when the shooting operation device 28 is operated so that the game ball flows down the left side area PA2, and the shooting operation is performed so that the game ball flows down the right side area PA3. When the device 28 is operated, winning is possible.

The configuration of the distribution winning apparatus 415 will be described with reference to FIG. 213 in addition to FIG. 209. FIG. 213 is a vertical cross-sectional view for explaining the internal configuration of the distribution winning apparatus 415.

As shown in FIG. 209, the distribution winning apparatus 415 includes a distribution entrance 441 having a size through which a game ball can pass, and the game ball cannot pass through the distribution entrance 441 and a closed state. The distribution side opening/closing member 442 is provided for switching to an open state in which a ball can pass. The distribution-side opening/closing member 442 is opened by being driven by the distribution inlet drive unit 443 through a link mechanism (not shown). The drive unit 443 for distribution entrance is electrically connected to the MPU 62 of the main controller 60, and the drive control of the drive unit 443 for distribution entrance is executed by the main CPU 63.

As shown in FIG. 213, the game balls that have won the distribution entrance 441 are led out to a branch passage 445 formed in the base body 444 of the distribution prize winning apparatus 415. The branch passage 445 has an upstream passage region 445a that is set so that the passage direction is laterally downwardly inclined from an inlet portion of the branch passage 445 to an intermediate position of the branch passage 445, and the upstream passage region 445a. The discharge passage region 445b which is continuous with the downstream end of the discharge passage region 445b and is set to be vertically downward, and the discharge passage region 445b which is provided by branching from the middle position of the discharge passage region 445b. It is provided with a V winning passage area 445c for guiding the ball. In this case, the size of the upstream passage region 445a in the direction orthogonal to the passage direction is equal to or more than one game ball and less than two game balls, so that the direction is orthogonal to the passage direction. The game balls are prevented from passing through the upstream passage region 445a in a state where the plurality of game balls are lined up. Therefore, a plurality of game balls are prevented from reaching the branch position of the discharge passage area 445b to the V winning passage area 445c at the same time.

A switching piece 446 for guiding the game ball flowing into the discharge passage area 445b to the V prize passage area 445c is provided at a branch point of the discharge passage area 445b to the V prize passage area 445c. The switching piece 446 is rotatably supported in a region on the opposite side of the V winning passage region 445c side with respect to the discharge passage region 445b of the base body 444, and is entirely retracted outside the discharge passage region 445b. It is displaceable between the position and the V guide position protruding into the discharge passage region 445b. The driving force of the switching drive unit 447 is transmitted to the switching piece 446 through a transmission unit (not shown). When the switching drive unit 447 is in the non-driving state, the switching piece 446 is arranged at the retracted position by the urging force of the urging means such as a spring (not shown), and the switching drive unit 447 is brought into the driven state by the urging force. The switching piece 446 is displaced against the biasing force and is arranged at the V guiding position. The switching drive unit 447 is electrically connected to the MPU 62 of the main controller 60, and the drive control of the switching drive unit 447 is executed by the main CPU 63.

When the switching piece 446 is arranged at the retreat position, the game ball flowing into the branch passage 445 flows down the discharge passage area 445b without being guided to the V winning passage area 445c. Then, the game ball is discharged to the rear of the game board 24 after being detected by the count detection sensor 448 provided downstream of the branch position by the switching piece 446 in the discharge passage region 445b. The count detection sensor 448 is electrically connected to the MPU 62 of the main control device 60, and based on the detection result of the count detection sensor 448, the main CPU 63 determines whether the count detection sensor 448 detects a game ball.

On the other hand, when the switching piece 446 is arranged at the V guiding position, the game ball that has flowed into the branch passage 445 is received by the switching piece 446 from below. The upper surface of the switching piece 446 in the state of being arranged at the V induction position is inclined downward toward the V winning path region 445c. As a result, the game ball received from below by the switching piece 446 flows into the V prize passage area 445c by its own weight and flows down the V prize passage area 445c. Then, the game ball is discharged to the rear of the game board 24 after being detected by the V-winning detection sensor 449 provided in the V-winning passage area 445c. The V winning detection sensor 449 is electrically connected to the MPU 62 of the main control device 60, and based on the detection result of the V winning detection sensor 449, the main CPU 63 identifies whether or not the game ball in the V winning passage area 445c has passed. To be done.

When the distribution-side opening/closing member 442 is in the open state, the period maintained in the open state is fixed at 10 seconds, which is longer than the firing cycle of the game ball, and is distributed in the distribution execution mode. The upper limit of the number of game balls that can be entered in the winning device 415 is fixed at 10. Further, in a situation where the firing operation device 28 is operated by the player, the game ball firing mechanism 27 is drive-controlled so that one game ball is fired toward the game area PA in 0.6 sec. In addition, the game ball flowing down the right side area PA3 reaches the position of the distribution side opening/closing member 442 unless it enters the second operating unit 413 or the special electric winning device 416 on the way. Then, if the distribution side opening/closing member 442 is in the open state, if the game balls continue to be launched so that the game balls flow toward the distribution winning device 415, the distribution winning device 415 has an upper limit. It is possible to win more than the winning number of game balls.

On the other hand, the switching piece 446 is arranged from the retracted position to the V guidance position at a timing 2 seconds after the distribution side opening/closing member 442 is opened, and then is moved to the V guidance position for 12 seconds. Retained. Then, when 12 seconds have elapsed, the V guidance position is returned to the retracted position. In this case, in a situation where the player operates the firing operation device 28 as described above, the game ball launching mechanism 27 is drive-controlled so that one game ball is launched toward the game area PA in 0.6 sec. Therefore, at the timing when the switching piece 446 is arranged at the V induction position, the number of winning prizes to the distribution winning apparatus 415 has not yet reached the upper limit winning number of the distribution execution mode, and the distribution side opening/closing member 442 is not operated. The open state is maintained. Further, as described above, the game ball flowing down the right side area PA3 reaches the position of the distribution side opening/closing member 442 unless it enters the second actuating portion 413 or the special electric winning device 416 on the way. Therefore, when the distribution side opening/closing member 442 is opened, if the game balls are continuously emitted so that the game balls flow down toward the distribution winning apparatus 415, the distribution side opening/closing member 442 is The switching piece 446 is arranged at the V induction position at the timing when the game ball that has won the distribution prize winning device 415 reaches the position of the switching piece 446 after 2 seconds have elapsed from the opening state. Therefore, in the distribution execution mode, the game ball is basically detected by the V winning detection sensor 449.

Whether the game ball is detected by the count detection sensor 448 or the game ball is detected by the V winning detection sensor 449, the same number of prize balls corresponding to the distribution winning device 415 are paid out. To be done. In addition, when the game ball is detected by the V winning detection sensor 449 in the distribution execution mode, the opening/closing execution mode is generated after the distribution execution mode. On the other hand, when the distribution execution mode ends without the game ball being detected by the V winning detection sensor 449, the opening/closing execution mode does not occur.

Next, an electrical configuration for the main CPU 63 to perform various kinds of lottery will be described with reference to FIG.

The main CPU 63 uses various counter information at the time of a game to perform a winning lottery, setting of display of special symbol display portions 425 and 426, setting of symbol display of the symbol display device 424, setting of display of the general symbol display portion 423a, etc. As shown in FIG. 214, specifically, as shown in FIG. 214, a winning random number counter C1 used for lottery for winning, a type counter C2 used when determining a big hit type and a small hit type, and a symbol display The reach random number counter C3 used for the reach generation lottery when the device 424 fluctuates, the random number initial value counter CINI used for setting the initial value of the hit random number counter C1, the special figure display parts 425, 426, and the symbol display device 424. The variation type counter CS that determines the display continuation period of the game time is used. Further, the universal electric accessory release counter C4 used in the lottery for determining whether or not the guidance unit 432 of the second operation unit 413 is in the guidance execution state is used. The counters C1 to C3, CINI, CS and C4 are provided in various counter areas 65b of the main RAM 65.

Each of the counters C1 to C3, CINI, CS, and C4 is a loop counter in which 1 is added to the previous value each time it is updated, and after reaching the maximum value, it returns to "0". Each counter is updated at short time intervals. The information corresponding to the winning random number counter C1, the type counter C2, and the reach random number counter C3 is a special figure holding area provided in the main side RAM 65 when the winning of the first operating unit 412 or the second operating unit 413 occurs. 451 is stored. The special figure reservation area 451 includes a first special figure reservation area 452, a second special figure reservation area 453, and a special figure execution area 454.

The first special figure reservation area 452 includes a first area 452a, a second area 452b, a third area 452c and a fourth area 452d, and a winning random number counter C1 according to the winning history of the first operating unit 412, Numerical information of each of the type counter C2 and the reach random number counter C3 is stored in any of the areas 452a to 452d as pending information on the special drawing side. In this case, in the first area 452a to the fourth area 452d, when the winning of the first operating portion 412 occurs a plurality of times in succession, the first area 452a→the second area 452b→the third area 452c→the fourth area. Numerical information is sequentially stored in the order of the four areas 452d. Since the four areas 452a to 452d are provided in this manner, the winning history of the game balls to the first actuating portion 412 can be reserved and stored up to a maximum of four. Note that the number that can be reserved and stored in the first special figure reservation area 452 is not limited to four and is arbitrary, and may be two, three, or five or more other numbers. , May be singular.

The second special figure reservation area 453 is provided with a first area 453a, a second area 453b, a third area 453c and a fourth area 453d, and a winning random number counter C1 according to the winning history to the second operating unit 413, Numerical information of each of the type counter C2 and the reach random number counter C3 is stored in any of the areas 453a to 453d as reserved information on the special drawing side. In this case, in the first area 453a to the fourth area 453d, when the winning of the second operating portion 413 occurs a plurality of times in succession, the first area 453a→the second area 453b→the third area 453c→the third area 453c. Numerical information is sequentially stored in the order of the four areas 453d. Since the four areas 453a to 453d are provided in this manner, the winning history of the game balls to the second operating unit 413 can be reserved and stored up to a maximum of four. In addition, the number that can be reserved and stored in the second special figure reservation area 453 is not limited to four, and may be any number, and may be two, three, or five or more other numbers. , May be singular.

The special figure execution area 454 is an area for storing pending information of a target for which a special figure is judged to be right or wrong or a type is determined when the variable display is started in any of the special figure display portions 425 and 426. Is. Specifically, when the variable display of the first special figure display unit 425 is started, the reservation information stored in the first area 452a of the first special figure reservation area 452 is moved to the special figure execution area 454. To be done. On the other hand, when the variable display of the second special figure display unit 426 is started, the reservation information stored in the first area 453a of the second special figure reservation area 453 is moved to the special figure execution area 454. In the following description, the holding information stored in the first special drawing holding area 452 and the holding information moved from the first special drawing holding area 452 to the special drawing execution area 454 are held on the first special drawing side. The information is referred to as information, and the holding information stored in the second special drawing holding area 453 and the holding information moved from the second special drawing holding area 453 to the special drawing execution area 454 are called holding information on the second special drawing side. ..

The information corresponding to the universal electric accessory release counter C4 is stored in the universal figure holding area 455 provided in the main side RAM 65 when a prize is awarded to the through winning portion 414. The universal figure holding area 455 is provided with a first area 455a, a second area 455b, a third area 455c and a fourth area 455d, and in accordance with the winning history of the through winning part 414, the universal electric accessory release counter C4. The numerical value information is stored in any of the areas 455a to 455d as the reservation information on the universal figure side. In this case, in the first area 455a to the fourth area 455d, when the winning in the through winning part 414 occurs a plurality of times in succession, the first area 455a→the second area 455b→the third area 455c→the fourth area. Numerical information is stored in time series in the order of the area 455d. Since the four areas 455a to 455d are provided in this manner, the winning history of the game balls to the through winning portion 414 can be reserved and stored up to a maximum of four. Note that the number that can be reserved and stored in the universal figure reservation area 455 is not limited to four, and may be any number, and may be other plural numbers such as two, three, or five or more. May be

An execution area 456 for a general figure is provided in the general figure reservation area 455. In the execution area 456 for a general figure, when the variable display is started on the general figure display unit 423a, the holding information of the target for conducting the guidance state lottery for determining whether or not the guidance unit 432 is in the guidance state is stored. This is the area to be stored. Specifically, when the variable display of the universal figure display unit 423a is started, the suspension information stored in the first area 455a of the universal figure suspension area 455 is moved to the universal figure execution area 456.

The counters C1 to C3, CINI, CS and C4 will be described in detail.

First, the general electric accessory opening counter C4 will be described. The general electric accessory release counter C4 is configured to be incremented by 1 in the range of 0 to 250 and returned to "0" after reaching the maximum value. The ordinary electric accessory release counter C4 is regularly updated, and is stored in the universal figure holding area 455 of the main side RAM 65 at the timing when the game ball wins the through winning portion 414. Then, at a predetermined timing, a guidance state lottery for determining whether or not to control the guidance unit 432 to the guidance state based on the stored value of the universal electric accessory release counter C4 is performed. As described above, the high-frequency support mode and the low-frequency support mode are set as the support mode of the guidance unit 432 (that is, the support mode of the second operation unit 413), and the guidance state of the guidance unit 432 (the second operation unit 413) is set. The open state) is controlled in a mode corresponding to the type of support mode at that time.

Next, the winning random number counter C1 will be described. The hit random number counter C1 is configured to be sequentially incremented by 1 in the range of 0 to 9999, and returned to "0" after reaching the maximum value. In particular, when the hit random number counter C1 makes one round, the value of the random number initial value counter CINI at that time is read as the initial value of the hit random number counter C1. The random number initial value counter CINI is a loop counter similar to the random number counter C1 (value=0 to 9999). The hit random number counter C1 is regularly updated, and is stored in the special figure reservation area 451 of the main side RAM 65 at the timing when the game ball wins the first operating unit 412 or the second operating unit 413. Then, the hit/miss determination processing is performed using the stored value of the hit random number counter C1.

The value of the random number that is won in the win/loss determination process is stored in the main ROM 64 as a win/loss table. As the win/loss table, a win/loss table 461 of the first special figure is provided in association with the hold information on the first special figure side, and a win/fail table of the second special figure is associated with hold information on the second special figure side. 462 is provided. Further, in the present embodiment, as the win/loss lottery mode, there is not a plurality of types of modes that differ the probability of a jackpot result, but the probability of a jackpot result is constant if the same setting value is set. One mode is set.

FIG. 215(a) is an explanatory diagram for explaining the win/loss table 461 of the first special figure, and FIG. 215(b) is an explanatory diagram for explaining the win/loss table 462 of the second special figure.

As shown in FIG. 215(a) and FIG. 215(b), there are a big hit result, a small hit result, and a miss result as the hit result of the hit determination process. The jackpot result is a win/fail result that can be a trigger to shift to the opening/closing execution mode in which the special electric winning device 416 is controlled to be opened/closed and a trigger to shift to the support mode. The small hit result becomes a trigger to shift to the sorting execution mode in which the sorting and prize winning apparatus 415 is controlled to open and close, and to shift to the opening and closing execution mode and the support mode when a V winning occurs in the sorting execution mode. On the other hand, in the case where the V winning is not generated in the distribution execution mode, it is the result of winning/judging which is not a trigger for shifting between the opening/closing execution mode and the support mode. The disengagement result is a hit/fail result that does not trigger the transition to the open/close execution mode and the distribution execution mode and further does not trigger the transition in the support mode.

As shown in FIG. 215(a), in the hit/miss table 461 of the first special figure, the jackpot result and the out-of-match result are set as the determination results of the hit/miss determination processing, but the small hit result is not set. Further, although the pachinko machine 10 has the setting states of “setting 1” to “setting 6”, a higher setting value has a higher probability of a jackpot result, and a higher setting value has a lower probability of a deviation result. Is set.

Specifically, the lowest setting value, “Setting 1”, is set to 50 as the number of pieces of numerical value information of the hit random number counter C1 which is a big hit result, and numerical value information of the hit random number counter C1 which is a deviation result. Is set to 9950. Also, in "Setting 2" which is a setting value one level higher than "Setting 1", 52 pieces are set as the number of numerical information of the hit random number counter C1 which is a jackpot result, and a hit random number counter which is a deviation result is set. 9948 is set as the number of numerical information of C1. Also, 54 is set as the number of pieces of numerical value information of the hit random number counter C1 which is a big hit result in "Setting 3" which is a setting value one step higher than that of "Set 2", and a hit random number counter which is a deviation result. 9946 pieces are set as the number of numerical information of C1. Further, in "Setting 4", which is a setting value one step higher than "Setting 3", 56 pieces are set as the number of numerical information of the hit random number counter C1 which is a big hit result, and a hit random number counter which is a deviation result is set. 9944 pieces are set as the number of numerical information of C1. Further, "setting 5", which is a setting value one step higher than "setting 4", is set with 58 as the number of pieces of numerical information of the hit random number counter C1 which is a jackpot result and a hit random number counter which is a deviation result. 9942 is set as the number of numerical information of C1. Further, in the "setting 6" which is the highest setting value, 60 is set as the number of numerical value information of the hit random number counter C1 which is a big hit result, and is also set as the number of numerical value information of the hit random number counter C1 which is a miss result. 9940 pieces are set.

In other words, the probability that a jackpot result will be 1/200 triggered by the hold information on the first special figure side in "Setting 1". In "setting 2", the probability of a jackpot result triggered by the hold information on the first special map side is about 1/192. In “Setting 3”, the probability that a jackpot result will be triggered by the pending information on the first special map side is about 1/185. In “Setting 4”, the probability that a jackpot result will be triggered by the pending information on the first special map side is about 1/179. In “Setting 5”, the probability that a jackpot result will be triggered by the pending information on the first special map side is about 1/172. In “Setting 6”, the probability that a jackpot result will be triggered by the pending information on the first special map side is about 1/167. Note that the numerical information of the hit random number counters C1 that is a big hit result may be set so as to be aggregated so as to be a serial number. It may be configured to have.

As shown in FIG. 215(b), the jackpot result, the jackpot result, and the miss result are set in the hit/miss table 462 of the second special figure as the judgment result of the hit/miss judgment processing. Further, although the pachinko machine 10 has the setting states of “setting 1” to “setting 6”, a higher setting value has a higher probability of a jackpot result, and a higher setting value has a lower probability of a deviation result. Is set. On the other hand, the probability of a small hit result is set to be the same regardless of "Setting 1" to "Setting 6".

Specifically, the lowest setting value "Setting 1" is set to 50 as the number of pieces of numerical value information of the winning random number counter C1 which is a big hit result, and the numerical value of the winning random number counter C1 which is a small hit result. 2000 pieces are set as the number of pieces of information, and 7950 pieces are set as the number of pieces of numerical value information of the random number counter C1 which results in the deviation. Moreover, 52 pieces are set as the number of pieces of numerical information of the hit random number counter C1 which is a big hit result, in the "setting 2" which is a setting value one step higher than the "set 1", and the hit random number which is a small hit result is set. The number of numerical value information of the counter C1 is set to 2000, and the number of numerical value information of the random number counter C1 which is a deviation result is set to 7948. Moreover, 54 pieces are set as the number of pieces of numerical value information of the hit random number counter C1 which is a big hit result, in the "setting 3" which is a set value one step higher than the "set 2", and the hit random number which is a small hit result is set. The number of pieces of numerical information of the counter C1 is set to 2000, and the number of pieces of numerical information of the random number counter C1 which is a deviation result is set to 7946. Further, in "Setting 4", which is a setting value one step higher than "Setting 3", 56 pieces are set as the number of numerical value information of the hit random number counter C1 which is a big hit result, and the hit random number which is a small hit result is set. 2000 is set as the number of numerical information of the counter C1, and 7944 is set as the number of numerical information of the random number counter C1 which is a deviation result. Further, "setting 5" which is a setting value one step higher than "setting 4" is set with 58 pieces of numerical information of the hit random number counter C1 which is a big hit result, and the random number which is a small hit result is set. 2000 is set as the number of numerical information of the counter C1, and 7942 is set as the number of numerical information of the random number counter C1 which is a deviation result. Further, in the "setting 6" which is the highest setting value, 60 pieces are set as the number of pieces of numerical value information of the hit random number counter C1 which is a big hit result, and the number of pieces of numerical value information of the hit random number counter C1 which is a small hit result is set. Is set to 2000, and 7940 is set as the number of numerical value information of the random number counter C1 which is a deviation result.

That is, in "Setting 1", the probability that the jackpot result is triggered by the holding information on the second special figure side is 1/200, which is the same as the probability that the jackpot result is triggered by the holding information on the first special figure side. In "Setting 2", the probability of a jackpot result triggered by the holding information on the second special figure side is about 1/192, which is the same as the probability of a jackpot result triggered by the holding information on the first special figure side. In "Setting 3", the probability of a jackpot result triggered by the holding information on the second special figure side is about 1/185, which is the same as the probability of a jackpot result triggered by the holding information on the first special figure side. In "Setting 4", the probability of a jackpot result triggered by the holding information on the second special figure side is about 1/179, which is the same as the probability of a jackpot result triggered by the holding information on the first special figure side. In "Setting 5", the probability of a jackpot result triggered by the holding information on the second special figure side is about 1/172, which is the same as the probability of a jackpot result triggered by the holding information on the first special figure side. In "Setting 6", the probability of a jackpot result triggered by the holding information on the second special figure side is about 1/167, which is the same as the probability of a jackpot result triggered by the holding information on the first special figure side.

The probability that a small hit result is triggered by the hold information on the second special map side is 1/5 which is the same regardless of which of "Setting 1" to "Setting 6". This small hit result has a higher probability than the large hit result regardless of any of "Setting 1" to "Setting 6". Note that the numerical information of the hit random number counters C1 that is a big hit result may be set so as to be aggregated so as to be a serial number. It may be configured to have. Further, the numerical value information of the hit random number counters C1 which is a small hit result may be set so as to be aggregated so as to be a serial number. It may be configured to have.

As described above, the higher the set value, the higher the probability that the jackpot result will be, regardless of whether the holding information on the first special map side is the trigger or the holding information on the second special map side is the trigger. The higher the set value, the more advantageous it is for the player. In addition, the opening and closing execution mode is a period in which the increase amount of the player's ball per unit time is the largest, and the probability of the jackpot result that triggers the transition of the opening and closing execution mode varies according to the set value, It is possible to increase the player's attention to the set value.

In such a configuration in which the probability of a big hit result fluctuates according to the set value, the probability of a small hit result is the same regardless of "Setting 1" to "Setting 6". This makes it possible for the player to limit his or her attention to the jackpot result in order to infer the set value, making it difficult to infer the set value.

Further, in the hit/miss table 462 of the second special figure, any set value deviates from the number of numerical information of the hit random number counter C1 assigned to the small hit result, and the hit random number counter C1 assigned to the result. In a configuration in which the number of numerical information items of the above is larger, the variation due to the set value of the number of numerical information items of the hit random number counter C1 assigned to the jackpot result is the numerical value information of the hit random number counter C1 assigned to the outlier result. Absorbed by fluctuations in the number of. Also from this point, it is possible to make it difficult to guess the set value.

Next, the type counter C2 will be described. The type counter C2 is configured to be sequentially incremented by 1 within the range of 0 to 29, and then returned to "0" after reaching the maximum value. The type counter C2 is regularly updated, and is stored in the special figure holding area 451 of the main side RAM 65 at the timing when the game ball wins the first operating unit 412 or the second operating unit 413. Then, the type determination processing is performed using the stored value of the type counter C2.

The type determination process using the type counter C2 is performed when the jackpot result and the small hit result are obtained in the hit determination process. That is, in the present embodiment, a plurality of types of big hit results are set and a plurality of types of small hit results are set. When the jackpot result is selected in the hit/miss determination process, the jackpot result type is selected by using the jackpot type table 463 and the type counter C2 stored in advance in the main ROM 64. When the small hit result is selected in the hit/miss determination process, the small hit result type is selected using the small hit type table 464 and the type counter C2 stored in advance in the main ROM 64. The types of big hit results and the types of small hit results will be described below.

FIG. 216(a) is referred to in order to sort the types of the jackpot results when the jackpot result is selected in the hit determination process triggered by the hold information on the first special diagram side or the hold information on the second special diagram side. It is explanatory drawing for demonstrating the classification table 463 for big hits. In addition, FIG. 216(b) is an explanatory diagram for explaining the contents of each of a plurality of types of jackpot results.

The jackpot type table 463 is referred to when the jackpot result is selected in the hit determination process triggered by the holding information for the first special figure, and the hit determination is triggered by the holding information for the second special figure. Referenced when the jackpot result is selected in the processing. That is, when the jackpot result is selected in the hit/miss determination process triggered by the hold information for the first special figure, and when the jackpot result is selected in the hit determination process triggered by the hold information for the second special figure. In either case, the same jackpot type table 463 is referred to.

In the jackpot type table 463, as shown in FIG. 216(a), 6R jackpot results and 15R jackpot results are set as the jackpot result types. The numerical information of the type counter C2 of "0 to 26" corresponds to the 6R jackpot result, and the numerical information of the type counter C2 of "27 to 29" corresponds to the 15R jackpot result. That is, when the jackpot result is selected in the hit determination process, the 6R jackpot result is selected with a probability of 9/10, and the 15R jackpot result is selected with a probability of 1/10.

When the 6R jackpot result is obtained, the round game occurs 6 times in the subsequent opening/closing execution mode as shown in FIG. 216(b). After the opening/closing execution mode ends, the high-frequency support mode is set regardless of the support mode before the opening/closing execution mode is started. In this high frequency support mode, if the hold information that triggered the occurrence of the 6R jackpot result is the hold information on the first special map side, the game time is triggered by the hold information on the second special map side. If it has been executed once, the process ends and shifts to the low-frequency support mode. As described above, the first to fourth areas 453a to 453d are provided in the second special figure reservation area 453, and four pieces of reservation information on the second special figure side can be reserved and stored. Therefore, four in the second operating unit 413 controlled in the high-frequency support mode in a situation where the first game time triggered by the hold information on the second special map side is executed after the opening/closing execution mode ends. By entering the game ball, it becomes possible to execute the game times five times triggered by the hold information on the second special map side after the opening/closing execution mode ends.

On the other hand, if the hold information that triggered the occurrence of the 6R jackpot result was the hold information on the second special map side, the game time was executed five times triggered by the hold information on the second special map side. In this case, the process is terminated and the low frequency support mode is entered. As described above, the first to fourth areas 453a to 453d are provided in the second special figure reservation area 453, and four pieces of reservation information on the second special figure side can be reserved and stored. Therefore, after the opening/closing execution mode ends, in the second operation unit 413 which is controlled in the high frequency support mode in the situation where the fifth game time triggered by the hold information on the second special map side is being executed, By entering individual game balls, it is possible to execute nine game times triggered by the hold information on the second special map side after the opening/closing execution mode ends.

When the 15R jackpot result is obtained, a round game occurs 15 times in the subsequent opening/closing execution mode as shown in FIG. 216(b). Therefore, the 15R jackpot result is more advantageous than the 6R jackpot result at least in terms of the number of round game executions. After the opening/closing execution mode ends, the high-frequency support mode is set regardless of the support mode before the opening/closing execution mode is started. In this high-frequency support mode, even if the pending information that triggered the 15R jackpot result is either the pending information on the first special figure side or the pending information on the second special figure side, When the game times triggered by the hold information are executed five times, the game ends and the mode shifts to the low frequency support mode. As described above, the first to fourth areas 453a to 453d are provided in the second special figure reservation area 453, and four pieces of reservation information on the second special figure side can be reserved and stored. Therefore, after the opening/closing execution mode ends, in the second operation unit 413 which is controlled in the high frequency support mode in the situation where the fifth game time triggered by the hold information on the second special map side is being executed, By entering individual game balls, it is possible to execute nine game times triggered by the hold information on the second special map side after the opening/closing execution mode ends.

FIG. 216(c) shows a type table 464 for small hits, which is referred to when the small hit result is selected in the hit determination process triggered by the holding information on the second special figure side, to sort the type of the small hit result. It is an explanatory view for explaining. In addition, FIG. 216(d) is an explanatory diagram for explaining the respective contents of a plurality of types of small hit results. As described above, since the small hit result is not selected in the hit determination process triggered by the hold information on the first special map side, a small number is set in the game times triggered by the hold information on the first special map side. The hit type table 464 is not referred to.

As shown in FIG. 216(c), in the small hit type table 464, the first small hit result, the second small hit result, and the third small hit result are set as the small hit result types. Then, the numerical information of the type counter C2 of "0 to 9" corresponds to the first small hit result, and the numerical information of the type counter C2 of "10 to 19" corresponds to the second small hit result, The numerical information of the type counter C2 of "20 to 29" corresponds to the third small hit result. That is, when the small hit result is selected in the hit/miss determination process, the first small hit result is selected with a probability of 1/3, the second small hit result is selected with a probability of 1/3, and is reduced to 1/3. The third small hit result is selected with a probability of.

Regardless of the first small hit result, the second small hit result, and the third small hit result, the distribution execution mode is first started as shown in FIG. 216(d). In this distribution execution mode, the distribution winning apparatus 415 is opened and closed once. As described above, the distribution winning device 415 is in the open state when the opening continuation period of 10 seconds has elapsed, and the number of game balls entering the distribution winning device 415 reaches the upper limit prize winning number of 10. If either condition is met, the process is continued. Then, in a situation where the distribution winning device 415 is kept open, the shooting operation is continued so that the game balls flow down toward the distribution winning device 415, so that the distribution winning device 415 is entered. A V prize is generated in which the game ball is detected by the V prize detection sensor 449. Even if a plurality of game balls are detected by the V-winning detection sensor 449 in one distribution execution mode, the number of V-winning occurrences is treated as one.

When the V prize is generated, the opening/closing execution mode is generated thereafter. In this case, if it is after the distribution execution mode triggered by the first small hit result, it becomes the open/close execution mode in which five round games are executed, and if it is the distribution execution mode triggered by the second small hit result. For example, it becomes an opening/closing execution mode in which eight round games are executed, and becomes an opening/closing execution mode in which fourteen round games are executed if the distribution execution mode is triggered by the third small hit result. Therefore, the second small hit result is more advantageous than the first small hit result, and the third small hit result is more advantageous than the second small hit result, at least in terms of the number of times the round game is executed.

If one of the first small hit result, the second small hit result, and the third small hit result becomes a V winning in the distribution execution mode and the opening/closing execution mode occurs, the opening/closing execution mode is ended. After that, the high-frequency support mode is set regardless of the support mode before the start of the distribution execution mode. This high-frequency support mode, even if any of the first small hit result, the second small hit result, and the third small hit result as a trigger, game times triggered by the hold information on the second special map side Is executed 5 times, the process is terminated and the low frequency support mode is entered. As described above, the first to fourth areas 453a to 453d are provided in the second special figure reservation area 453, and four pieces of reservation information on the second special figure side can be reserved and stored. Therefore, after the opening/closing execution mode ends, in the second operation unit 413 which is controlled in the high frequency support mode in the situation where the fifth game time triggered by the hold information on the second special map side is being executed, By entering individual game balls, it is possible to execute nine game times triggered by the hold information on the second special map side after the opening/closing execution mode ends. In addition, when the V winning is not generated in the distribution execution mode triggered by any one of the first small hit result, the second small hit result and the third small hit result, the distribution execution mode is The open/close execution mode does not occur after the end, and the support mode before the start of the distribution execution mode is maintained.

The flow of the game when the win/loss tables 461 and 462 and the type tables 463 and 464 are set as described above will be described. At the beginning of the game hall business, the support mode is basically the low frequency support mode. In the low-frequency support mode, a firing operation is performed aiming at winning in the first operating unit 412, and when a winning in the first operating unit 412 occurs, the variable display of the pattern is displayed on the first special figure display unit 425. A game time in which the symbol display is performed and the variable display of the symbol is performed is executed. The open/close execution mode is generated after the end of the game time by selecting the jackpot result in the hit/miss determination process executed at the start of the game time. In this opening/closing execution mode, the round game is executed 6 times if the 6R jackpot result is an occurrence trigger, and the round game is executed 15 times if the 15R jackpot result is an occurrence trigger.

After the open/close execution mode ends, the high-frequency support mode is set. In this case, the high-frequency support mode is ended when the game number in the second special figure display unit 426 is executed once if the jackpot result that triggered the occurrence of the opening/closing execution mode is the 6R jackpot result, If the jackpot result that triggered the occurrence of the opening/closing execution mode is the 15R jackpot result, the game is ended when the game number in the second special figure display unit 426 is executed five times. When the high frequency support mode is ended when the game number in the second special figure display unit 426 is executed once, it is possible to execute the game number five times triggered by the hold information on the second special figure side. Therefore, if the high frequency support mode is terminated when the game number in the second special figure display unit 426 is executed five times, the game number is executed nine times triggered by the hold information on the second special figure side. Is possible.

In the high-frequency support mode, a firing operation is performed aiming at a winning of the second operating unit 413, and when a winning of the second operating unit 413 occurs, a variable display of the pattern is displayed on the second special figure display unit 426. A game time in which the symbol display is performed and the variable display of the symbol is performed is executed. In the game times triggered by the hold information on the side of the second special map, a small hit result is obtained with a high probability of 1/5. When the small hit result is obtained, the distribution execution mode is set, and in the distribution execution mode, the V-win is basically generated by continuing the firing operation aiming at winning the prize in the distribution winning apparatus 415. When the V winning is generated, the opening/closing execution mode is generated thereafter. In this opening/closing execution mode, if the first small hit result is a trigger, the round game is executed 5 times, if the second small hit result is a trigger, the round game is executed 8 times, and the third small hit result is If it occurs, the round game is executed 14 times. After the opening/closing execution mode ends, regardless of whether the trigger is the first small hit result, the second small hit result, or the third small hit result, the high frequency support mode is set and the high frequency support mode is It is ended when the game times in the second special figure display unit 426 are executed five times. In this case, it is possible to execute the game game nine times triggered by the hold information on the second special map side.

In other words, when the transition to the high-frequency support mode occurs, a small hit result occurs in the game time triggered by the hold information on the second special map side, and the distribution execution mode and the open/close execution mode are generated. In addition to being able to perform, it is possible to subsequently execute the game times nine times triggered by the hold information on the second special figure side. As a result, the player expects that the transition to the high frequency support mode will occur, and when the transition to the high frequency support mode occurs, the game time is triggered by the hold information on the second special map side. It is expected that the result will be a small hit. Therefore, it becomes possible to improve the interest of the game. It should be noted that the jackpot result may occur in the game times triggered by the hold information on the second special figure side, and when the jackpot result occurs, the open/close execution mode occurs. Further, after the opening/closing execution mode ends, regardless of the kind of the jackpot result that has triggered the occurrence, the high frequency support mode is set and the high frequency support mode is executed five times in the second special map display unit 426. Will be terminated.

Next, the reach random number counter C3 will be described. The reach random number counter C3 is configured to be sequentially incremented by 1 in the range of 0 to 238, for example, and after reaching the maximum value, returns to "0". The reach random number counter C3 is periodically updated and is stored in the special figure reservation area 451 of the main side RAM 65 at the timing when the game ball wins the first operating unit 412 or the second operating unit 413. Then, by using the stored value of the reach random number counter C3, it is determined whether or not the reach display is generated in the game times that result in the deviation.

Here, in the pachinko machine 10, an expected effect is set as a kind of display effect in the symbol display device 424. The expected effect is provided with a symbol display device 424 capable of performing variable display of symbols, and in a game machine in which the final stop result is a grant corresponding result in a game time that is a big hit result or a small hit result, a symbol display It is a display state for making the player think that the variation display state is likely to be the above-mentioned assignment correspondence result in a stage before the stop result is derived and displayed after the variation display of the symbols in the device 424 is started. In addition, as for the assignment correspondence result, specifically, a combination of symbols having the same number is stopped and displayed on any of the activated lines.

Two types of expected display are set: a reach display and a notice display for expecting the occurrence of the reach display or the result of the assignment response in the stage before the reach display occurs.

In the reach display, the symbols are stopped and displayed for a part of the symbol rows displayed on the display surface of the symbol display device 424, thereby displaying a combination of the reach symbols, and the remaining symbols in that state. A display state in which variable display of symbols is displayed in a row is included. Also, in the state where the reach symbol combination is displayed as described above, while performing the variable display of the symbols in the remaining symbol columns, the reach effect is displayed by displaying a predetermined character or the like as a moving image on the background screen. , A combination of reach patterns is displayed in a reduced size or hidden, and a reach effect is included by displaying a predetermined character or the like as a moving image on substantially the entire display surface.

In the notice display, after the variable display of the symbols is started on the display surface of the symbol display device 424, the symbols are variably displayed in all the symbol columns, or a part of the symbol columns and the plurality of symbol columns are displayed. In the situation where the symbols are variably displayed in the symbol row, a mode in which the character is displayed separately from the symbols on the symbol row is included. Further, it also includes a background screen having a predetermined mode different from the previous modes and a pattern on the symbol row having a predetermined mode different from the previous modes. Such advance notice display can occur at both game times when the reach display is performed and when the reach display is not performed, but the reach display is higher than the case where the reach display is not performed. It is set to occur with a probability.

The reach display is executed regardless of the value of the reach random number counter C3 in the game times in which the same symbol combination is finally stopped and displayed, that is, in the game times corresponding to the big hit result or the small hit result. Further, in the game times corresponding to the deviation result, when the reach random number counter C3 acquired at a predetermined timing by referring to the reach table stored in the main ROM 64 corresponds to the occurrence of the reach display. ..

On the other hand, the decision as to whether or not to display the advance notice is made in the sound emission control device 81, not in the main control device 60. In this case, the sound emission control device 81 is more likely to give a notice display in the game times corresponding to any of the big hit results or the small hit results than in the game times corresponding to the miss result, and the appearance rate. The lottery process for displaying the advance notice is executed so as to satisfy at least one of the conditions that the low advance notice is likely to occur. By the way, the result of the lottery is reflected when the game display effect is executed on the symbol display device 424.

Next, the fluctuation type counter CS will be described. The fluctuation type counter CS is configured to be incremented by 1 in the range of 0 to 198, for example, and return to "0" after reaching the maximum value. The fluctuation type counter CS is used when the main CPU 63 determines the display continuation period of the variable display of the symbols on the special figure display portions 425, 426 and the display continuation period of the variable display of the symbols on the symbol display device 424. The fluctuation type counter CS is repeatedly updated, and is acquired at the time of starting the fluctuation of the pattern on the special figure display portions 425 and 426 and at the time of determining the fluctuation pattern at the start of the fluctuation of the symbol by the symbol display device 424.

<Universal control system processing>
Next, various processes executed by the main CPU 63 will be described. FIG. 217 is a flowchart showing the universal figure/universal control process executed by the main CPU 63. It should be noted that the universal figure/universal control process is executed in step S8914 in the first timer interrupt process (FIG. 133). Further, the processes of steps SD601 to SD610 in the universal figure/general electric power control process are executed by using the specific control program and the specific control data in the main CPU 63.

First, the process of acquiring the reservation information on the universal figure side is executed (step SD601). In the acquisition process, when a prize has been awarded to the through prize winning unit 414, and when the upper limit number of holding information on the universal figure side has not been acquired in the universal figure holding area 455, the general electric outlet release counter C4 is released. The numerical value information of is stored in the universal figure holding area 455. In this case, the reservation information on the universal figure side is stored in the order of the first area 455a, the second area 455b, the third area 455c, and the fourth area 455d.

After that, the numerical information of the universal figure universal communication counter provided in the main side RAM 65 is read (step SD602), and the universal figure universal communication address table provided in the main side ROM 64 is read (step SD603). Then, the start address corresponding to the numerical information of the POU/UDEN counter is obtained from the POU/DET address table (step SD604), and the process jumps to the process indicated by the obtained start address (step SD605).

The universal figure/universal counter is a counter for the main CPU 63 to know which of the processes from step SD606 to step SD610 in the universal figure/universal control process should be executed. In the address table, the start address in the program for executing each processing of step SD606 to step SD610 is set in correspondence with the numerical information of the Uzu-Uden counter. When the value of the universal figure/universal counter is “0”, jump to the universal figure variation start processing in step SD606, and when the value of the universal figure/universal counter is “1”, universal figure variation in step SD607. If the value of the universal figure/universal counter is “2”, the process jumps to the regular figure finalizing process of step SD608, and if the value of the universal figure/universal counter is “3” If the value of the universal figure universal communication counter is "4", the process jumps to step SD609 during the universal communication opening process, and the process jumps to step SD610 during the universal communication close process.

In the universal figure fluctuation start process of step SD606, the universal figure pending information stored in the universal figure pending area 455 is reserved, provided that the universal page pending information is pending stored in the universal figure pending area 455. The process of shifting is executed. Specifically, the reservation information on the universal figure side stored in the first area 455a of the universal figure reservation area 455 is shifted to the execution area 456 for the universal figure, and then the second area 455b→the first area 455a, The reservation information on the universal figure side is shifted so that the third area 455c→the second area 455b and the fourth area 455d→the third area 455c. Then, the guidance state lottery process is executed using the newly-held information on the universal figure side, which has been newly shifted to the universal figure execution area 456, as the lottery value. In the present embodiment, as described above, there are the low frequency support mode and the high frequency support mode as the support modes. However, the probability of winning the guiding state in the guiding state lottery process is the same in the low frequency support mode and the high frequency support mode (specifically, 4/5).

When the guidance state lottery process is executed in the universal figure fluctuation start process, a process for starting variable display of the pattern on the universal figure display unit 423a is executed. In this case, the information on the display continuation period during which the pattern is variably displayed on the universal figure display unit 423a is set in the universal figure universal timer counter provided in the main RAM 65. The value set in the universal figure/universal timer counter is decremented by 1 each time the timer updating process (step S8910) of the first timer interrupt process (FIG. 133) is executed. In this case, the display continuation period is shorter in the high frequency support mode than in the low frequency support mode. Specifically, the display continuation period is 1 second in the high frequency support mode, and the display continuation period is 10 seconds in the low frequency support mode. Then, after the variable display of the picture is started on the universal figure display unit 423a, the value of the universal figure universal communication counter is updated from "0" to "1". As a result, the process to be executed in the next processing time of the universal figure/universal control process becomes the universal figure changing process.

In the universal figure changing process of step SD607, a process for updating the display of the pattern on the universal figure display portion 423a is executed. Further, when the value set in the universal figure universal communication timer counter of the main RAM 65 in the universal figure variation start process is "0", the information of the fixed period on the universal figure side is transferred to the universal figure of the main RAM 65. In order to stop and display the pattern corresponding to the result of the guidance state lottery process that has been set on the universal electric timer counter and has triggered the execution of the variable display time of the current pattern on the universal pattern display unit 423a. Execute the process. Then, the value of the Uzu-Uden counter is updated from "1" to "2". As a result, the process to be executed in the next processing time of the universal figure universal communication control process becomes the universal figure finalizing process.

In the universal figure finalizing process of step SD608, when the value of the universal figure universal electric timer counter is “0”, the result of the guidance state lottery process that triggers the execution of the variable display of the current pattern is guided. It is determined whether or not the state is won. If the induction state is not elected, the value of the universal figure/general counter is cleared to “0”. As a result, the process to be executed in the next processing time of the universal figure/universal control process becomes the universal figure variation start process.

In the case of the guided state winning, a process for bringing the guiding unit 432 of the second operating unit 413 into the guided state is executed. In this case, in the high frequency support mode, the guidance unit 432 is set to 3 times as the guidance state, and the upper limit guidance period in the execution times of each guidance state is set to 2 seconds. On the other hand, in the low frequency support mode, the number of times the guidance unit 432 is in the guidance state is set to 1 and the upper limit guidance period in the execution times of the guidance state is set to 0.6 seconds. Information on the number of times the guidance state is executed is set in the universal electric power open counter provided in the main RAM 65, and information on the upper limit induction period is set in the universal figure universal electric timer counter. Further, in both the high frequency support mode and the low frequency support mode, the upper limit winning number of game balls to the second operating unit 413 when the guiding state is won is 10. Information on the upper limit winning number is set in the ordinary electric prize winning counter provided in the main RAM 65. When the value of the ordinary electric prize winning counter becomes “0”, the execution of the guidance state triggered by the present guidance state winning is ended. Further, by starting the output of the drive signal to the guide drive section 436, the guidance unit 432 is switched from the non-guidance state to the guidance state. After the setting for enabling execution of the guidance state as described above, the value of the Uzu-Uden counter is updated from "2" to "3". As a result, the process to be executed in the next processing time of the universal figure/universal electric power control process is the universal electric power open process.

In the ordinary electric power open process of step SD609, when a prize is generated in the second operating unit 413, the value corresponding to the number of winning prizes is subtracted from the value of the ordinary electric prize counter of the main RAM 65. When the value of the ordinary prize winning counter is “0”, the guidance unit 432 is switched from the guidance state to the non-guidance state by stopping the output of the drive signal to the guide driving unit 436, and Clear the value of the Hoden counter to "0". As a result, the process to be executed in the next processing time of the universal figure/universal control process becomes the universal figure variation start process. In addition, even if the value of the Poden winning counter is not "0", if the value of the universal figure normal electric timer counter is "0", the output of the drive signal to the guide drive unit 436 is stopped. As a result, the guidance unit 432 is switched from the guidance state to the non-guidance state, and the value of the universal power release frequency counter is decremented by one. Then, when the value of the universal power release counter is not "0", the information of the non-induction duration of the induction unit 432 is set in the universal communication timer counter, and then the value of the universal communication counter is set to "3". To "4". As a result, the process to be executed in the next processing time of the universal diagram/general electric power control process is the regular electric power system closing process. When the value of the universal power release counter is "0", the value of the universal communication universal counter is cleared to "0". As a result, the process to be executed in the next processing time of the universal figure/universal control process becomes the universal figure variation start process.

In the normal electric power closing process of step SD610, the guidance unit 432 is started by starting the output of the drive signal to the guide driving unit 436 on condition that the value of the general electric power universal electric timer counter is “0”. The information on the upper limit induction period is set in the universal communication timer counter while switching from the non-induction state to the induction state. Then, the value of the Uzu-Uden counter is updated from "4" to "3". As a result, the process to be executed in the next processing time of the universal figure/universal electric power control process is the universal electric power open process.

As a result of the normal/general electric power control processing being executed as described above, the variable display of the pattern is performed on the normal/general display unit 423a triggered by the occurrence of a prize in the through winning prize unit 414. Then, when the guidance state is won in the guidance state lottery process, the guidance unit 432 of the second operating unit 413 is in the guidance state. When the second operating unit 413 is in the guiding state, it is possible to win the game ball to the second operating unit 413, and when the game ball is won to the second operating unit 413, the holding information on the second special map side is displayed. It is stored in the second special figure reservation area 453.

<Special map special power control processing>
FIG. 218 is a flowchart showing a special figure special power control process executed by the main CPU 63. The special figure special power control process is executed in step S8913 in the first timer interrupt process (FIG. 133). Further, the processing of steps SD701 to SD713 in the special figure special power control processing is executed using the program for specific control and the data for specific control in the main CPU 63.

First, a process of acquiring pending information is executed (step SD701). In the process of obtaining the reservation information, when a winning is generated in the first operating unit 412, the number of pieces of the reservation information on the first special figure side stored in the first special figure holding area 452 is the upper limit storage number (specifically, If the number is less than 4), the storage process of the pending information on the first special figure side is executed. In the storage processing, the numerical information of the hit random number counter C1, the type counter C2, and the reach random number counter C3 is used as the holding information on the first special figure side, and the first area 452a to the fourth area 452d of the first special figure holding area 452 are set. In the area where the reservation information on the side of the first special figure in FIG. When the pending information on the first special figure side is acquired, the display content of the first special figure pending display section 427 is updated according to the increase in the number of the pending information on the first special figure side this time. Data setting to do so. When the hold information on the first special figure side is acquired, the hold increase command is transmitted to the sound emission control device 81. As a result, the image for notifying the number of holding storages of the holding information on the first special figure side in the symbol display device 424 is updated in correspondence with the new acquisition of the holding information on the first special figure side.

When a prize is generated in the second operating unit 413, the number of pieces of pending information on the second special figure side stored in the second special figure holding area 453 is less than the upper limit storage number (specifically, four pieces). The storage process of the pending information on the second special figure side is executed on the condition that In the storage processing, the numerical information of the hit random number counter C1, the type counter C2, and the reach random number counter C3 is used as the holding information on the second special figure side, and the first area 453a to the fourth area 453d of the second special figure holding area 453 are set. It is stored in the area in which the digestion order is earlier among the areas in which the reservation information on the second special figure side in FIG. When the hold information on the second special figure side is acquired, the display content of the second special figure hold display section 428 is updated in accordance with the increase in the number of hold information on the second special figure side this time. Data setting to do so. Further, when the hold information on the second special figure side is acquired, the hold increase command is transmitted to the sound emission control device 81. As a result, the image for notifying the number of held storages of the holding information on the second special figure side in the symbol display device 424 is updated in correspondence with the new acquisition of the holding information on the second special figure side.

After executing the acquisition processing of the hold information, the special figure special electric address table stored in the main side ROM 64 is read (step SD702). Then, the start address corresponding to the numerical information of the special figure special telephone address table is acquired (step SD703), and the process jumps to the processing indicated by the acquired start address (step SD704).

The special figure special telephone counter is a counter for the main CPU 63 to know which of the processes of steps SD705 to SD713 in the special figure special electricity control process should be executed. Indicates the start address in the program for executing each processing of step SD705 to step SD713 in correspondence with the numerical information of the special figure special power counter. If the value of the special figure special power counter is "0", the process jumps to the special figure variation start process of step SD705, and if the value of the special figure special power counter is "1", the special figure variation process of step SD706. If the value of the special figure tokuden counter is “2”, the process jumps to step SD707 during special figure fixing, and if the value of the special figure tokuden counter is “3”, the operation of step SD708 is changed. If the value of the special figure special power counter is "4", the process jumps to the sorting process of step SD709, and if the value of the special figure special power counter is "5", the step starts. If the value of the special electricity starter counter is "6", the process jumps to the special electricity start process of SD710, and if the value of the special electricity discharge counter is "7", the process jumps to the special electricity opening process of step SD711. It jumps to the special electric power closing process of step SD712, and when the value of the special electric figure special electric power counter is "8", it jumps to the special electric power ending processing of step SD713. Hereinafter, each processing of steps SD705 to SD713 will be described individually.

<Special map fluctuation start processing>
First, the special figure variation start processing in step SD705 will be described with reference to the flowchart in FIG. 219. The processes of steps SD801 to SD818 in the special figure variation start process are executed using the specific control program and the specific control data in the main CPU 63.

In the special figure variation start processing, the data setting processing is executed (step SD802) on condition that the pending information on the first special figure side or the pending information on the second special figure side is stored (step SD801: YES). .. In the data setting process, when the second special figure holding area 453 stores the second special figure holding information, the first special figure holding area 452 acquires it before the second special figure holding information. Regardless of whether or not the held information on the side of the first special figure that has been acquired is set, the holding information on the side of the second special figure stored in the first area 453a of the second special figure holding area 453 of the game time is displayed. It is moved to the special drawing execution area 454 to be an execution target. As a result, it becomes possible to prioritize the hold information on the second special figure side as a trigger for executing the hit/miss determination processing over the hold information on the first special figure side, and also as a trigger for executing the game times. Become.

When the holding information on the second special figure side stored in the first area 453a of the second special figure holding area 453 is moved to the execution area 454 for special figures, it is stored in the second special figure holding area 453 thereafter. A process of shifting the retained information on the side of the generated second special figure is executed. In this data shift processing, the data stored in the first to fourth areas 453a to 453d are sequentially shifted to the lower area side. Specifically, the data in each area is shifted in the order of the second area 453b→the first area 453a, the third area 453c→the second area 453b, the fourth area 453d→the third area 453c, and the fourth area 453d. Is cleared to "0". In addition, in the data setting process, data setting is performed so that the display content of the second special figure reservation display unit 428 is updated in accordance with the decrease in the number of reservation information on the second special figure side this time. Further, in the data setting process, the hold decrease command is transmitted to the voice emission control device 81. As a result, the image for notifying the number of holding storages of the holding information on the second special figure side in the symbol display device 424 is updated in correspondence with the decrease of the holding information on the second special figure side.

On the other hand, in the data setting process, if the second special figure holding area 453 does not store the holding information on the second special figure side, the data stored in the first area 452a of the first special figure holding area 452 is specially drawn. Move to the execution area 454 for. Then, the process of shifting the data stored in the first special figure reservation area 452 is executed. This data shift processing sequentially shifts the data stored in the first to fourth areas 452a to 452d to the lower area side. Specifically, the data in each area is shifted in the order of the second area 452b→the first area 452a, the third area 452c→the second area 452b, the fourth area 452d→the third area 452c, and the fourth area 452d. Is cleared to "0". Further, in the data setting process, data setting is performed so that the display content of the first special figure reservation display unit 427 is updated in accordance with the decrease in the number of the reservation information on the first special figure side this time. Further, in the data setting process, the hold decrease command is transmitted to the voice emission control device 81. As a result, the image for notifying the number of held storages of the holding information on the first special figure side in the symbol display device 424 is updated in correspondence with the reduction of the holding information on the first special figure side.

After the data setting process is executed, the hit/miss determination process is executed (step SD803). In the winning/disapproval determination processing, if the holding information on the first special drawing side is stored in the execution area 454 for special drawings and the current game time is triggered by the holding information on the first special drawing side, the current pachinko The win/loss table 461 (see FIG. 215(a)) of the first special figure corresponding to the set value of the machine 10 is read from the main side ROM 64. Then, the numerical information about the hit random number counter C1 is read out from the holding information on the side of the first special map that triggered the start of the game this time, and the read numerical information is compared with the hit/miss table 461 of the first special map. By collating with each other, it is specified whether the result of the present success/failure determination processing is the big hit result or the out-of-match result.

On the other hand, in the hit/miss determination process, if the second special figure side hold information is stored in the special figure execution area 454 and the current game time is triggered by the second special figure side hold information, The win/loss table 462 (see FIG. 215(b)) of the second special figure corresponding to the setting value of the pachinko machine 10 is read from the main ROM 64. Then, the numerical information about the hit random number counter C1 is read out from the holding information on the side of the second special map that triggered the start of the game this time, and the read numerical information is stored in the hit/miss table 462 of the second special map. By collating with each other, it is specified whether the result of the hit determination processing this time is a big hit result, a small hit result, or a miss result.

When the result of the hit determination processing is the jackpot result (step SD804: YES), the type determination processing at the time of jackpot is executed (step SD805). In the jackpot type determination process, the jackpot type table 463 shown in FIG. 216(a) is read from the main ROM 64. If the hold information on the first special map side is the trigger for the current game, the numerical information about the type counter C2 is read out from the hold information on the first special map side and the second special map side is held. When the information is the trigger for the current game, the numerical information about the type counter C2 is read out from the holding information on the second special map side. Then, which of the 6R jackpot result and the 15R jackpot result set in the jackpot type table 463 corresponds to the numerical range of the jackpot result of which kind is read out? Identify.

After the jackpot type determination process is executed, "1" is set to the flag of the main RAM 65 corresponding to the type of the jackpot result identified in the type determination process (step SD806). The state of the flag to which "1" is set is cleared to "0" when the open/close execution mode ends.

After that, a stop result setting process for the jackpot result is executed (step SD807). Specifically, information on the stop mode of the pattern to be finally stopped and displayed in the current game game on the side of the first special map display unit 425 and the second special map display unit 426 that is the execution target of the game game. From the stop result table for jackpot results stored in advance in the main ROM 64, and the specified information is stored in the main RAM 65. In this jackpot result stop result table, the type of the stop mode of the pattern stopped and displayed on the first special figure display unit 425 or the second special figure display unit 426 is set differently for each kind of jackpot result. In step SD807, information on the stop mode of the pattern according to the type of the jackpot result identified in step SD805 is stored in the main RAM 65. It should be noted that the stop mode of the pattern may be set in a one-to-one correspondence with each jackpot result, or a plurality of types of stop modes of the pattern may be set for at least some of the jackpot results. A method of selecting a stop result for a jackpot result in which stop patterns of a plurality of types of patterns are set is arbitrary, but the stop result may be selected according to the value of the type counter C2, for example.

When the result of the hit/miss determination process is the small hit result (step SD808: YES), the type determination process for the small hit is executed (step SD809). In addition, as described above, when the hit/disapproval determination processing is executed for the hold information on the first special map side, the small hit result is not selected, and the hit information for the hold information on the second special map side is not selected. The small hit result may be selected when the determination process is executed. In the small hit type determination process, the small hit type table 464 shown in FIG. 216(c) is read from the main ROM 64. In addition, the numerical information about the type counter C2 is read out from the holding information on the side of the second special figure that has triggered the game this time. Then, the numerical information about the read type counter C2 is set in the small hit type table 464, and any one of the first small hit result, the second small hit result, and the third small hit result is small. Identify whether it corresponds to the numerical range of the hit result.

After executing the small hit type determination process, "1" is set to the flag of the main RAM 65 corresponding to the type of the small hit result identified in the type determination process (step SD810). The state of the flag in which "1" is set is cleared to "0" when the distribution execution mode ends when the opening/closing execution mode does not occur after the distribution execution mode ends, and the distribution execution mode ends. When the open/close execution mode occurs later, “0” is cleared when the open/close execution mode ends.

After that, the stop result setting process for the small hit result is executed (step SD811). Specifically, the stop result table for the small hit result stored in advance in the main ROM 64 is used to store the information on the stop mode of the design to be finally stopped and displayed in the second special figure display unit 426 in the current game time. The specified information is stored in the main RAM 65. In the stop result table for the small hit result, the type of the stop mode of the pattern stopped and displayed on the second special figure display unit 426 is set differently for each kind of the small hit result, and in step SD811. The information on the stop mode of the design according to the kind of the small hit result identified in step SD809 is stored in the main RAM 65. The information on the pattern mode selected in this case is different from the information on the pattern mode selected in the case of the jackpot result. In addition, the stop mode of the pattern may be set in a one-to-one correspondence with each small hit result, or a plurality of types of stop patterns of the patterns may be set for at least some of the small hit results. .. A method of selecting a stop result for a small hit result in which a plurality of types of patterns are set is arbitrary, but the stop result may be selected according to the value of the type counter C2, for example.

When the result of the hit determination processing is neither the big hit result nor the small hit result (step SD804 and step SD808: NO), the stop result setting process for the deviation result is executed (step SD812). Specifically, information on the stop mode of the pattern to be finally stopped and displayed in the current game game on the side of the first special map display unit 425 and the second special map display unit 426 that is the execution target of the game game. From the stop result table for the disconnection result stored in advance in the main ROM 64, and the specified information is stored in the main RAM 65. The information on the pattern mode selected in this case is different from the information on the pattern mode selected in the case of the big hit result and the information of the pattern mode selected in the case of the small hit result.

After executing any one of the stop result setting processes, a display continuation period grasping process is executed (step SD813). In this processing, the numerical information of the fluctuation type counter CS is acquired. Further, it is determined whether or not the reach display is generated on the symbol display device 424 in the current game. Specifically, when the game times related to the variation start this time is any of the big hit results or any of the small hit results, it is determined that the reach display is generated. In addition, even when there is no big hit result or any small hit result, the numerical information related to the reach random number counter C3 stored in the execution area 454 for special figures is the numerical information corresponding to the occurrence of the reach. In this case, it is determined that the reach display is generated.

When it is determined that the reach display occurs, the reach generation continuation period table stored in the main ROM 64 is referred to, and the display continuation period of the game time corresponding to the numerical value information of the fluctuation type counter CS of this time is acquired. To do. On the other hand, if it is determined that the reach display does not occur, the reach non-occurrence duration table stored in the main side ROM 64 is referred to, and the game time display corresponding to the numerical value information of the current variation type counter CS is displayed. Get duration. By the way, the display duration of the game times that can be obtained by referring to the reach non-occurrence duration table is different from the display duration of the game times that can be obtained by referring to the reach occurrence duration table.

After that, a variation command and a type command corresponding to the result of the present success/failure determination processing and the type determination processing, the type of the current support mode, and the processing result of step SD813 are selected from the main ROM 64 (step SD814). Then, the selected variation command and type command are transmitted to the voice emission control device 81 (step SD815). The sound emission control device 81 executes control for executing the game turn effect corresponding to the received variation command and type command.

After that, the variable display of the pattern is started on the side of the first special figure display unit 425 and the second special figure display unit 426 which is the execution target of the current game time (step SD816). The first special figure display section 425 and the second special figure display section are tables to be referred to by the main CPU 63 when the first special figure display section 425 or the second special figure display section 426 performs variable display of patterns. A variable display table for special drawings which is common to the 426 is stored in the main ROM 64 in advance. When the variable display of the pattern is executed in the first special figure display unit 425 or the second special figure display unit 426, the same variable display table is used regardless of the result of the hit/miss determination processing and the result of the type determination processing. It When the variable display of the pattern is performed on the first special figure display unit 425 or the second special figure display unit 426, the variable display of the pattern according to a predetermined pattern is repeated, but the variable display table for the special figure is not displayed. The control data for one rotation in the variable display of the pattern according to the predetermined pattern is set. Therefore, when the variable display of the pattern is performed in the first special figure display unit 425 or the second special figure display unit 426, the variable display table for special figures until the display continuation period of the game times determined in step SD813 elapses. Will be used repeatedly.

The contents of the variable display of the patterns on the first special figure display unit 425 and the second special figure display unit 426 are arbitrary. For example, all the display segments 425a and 426a are in a light emitting state in a predetermined order. The variable display may be performed, or the variable display of the pattern may be performed by causing some of the display segments 425a and 426a to emit light in a predetermined order such as two or three. The variable display of the pattern may be performed by blinking all the display segments 425a and 426a, and the variable display of the pattern is performed by blinking a part of the display segments 425a and 426a such as one or two. May be performed.

After that, the special display unit 429 is extinguished (step SD817). In the special display portion 429, when the opening/closing execution mode occurs, information corresponding to the number of round games that occur in the opening/closing execution mode is displayed. That is, when the opening/closing execution mode is triggered by the 6R jackpot result, a display corresponding to six round games is displayed on the special display unit 429 when the opening/closing execution mode is started. Further, when the opening/closing execution mode is triggered by the result of the 15R jackpot result, when the opening/closing execution mode is started, a display corresponding to 15 round games is displayed on the special display unit 429. When the opening/closing execution mode is generated due to the occurrence of a V prize in the distribution execution mode triggered by the first small hit result, the special display portion 429 displays 5 when the opening/closing execution mode is started. A display corresponding to the round game is performed. Further, when the opening/closing execution mode is generated due to the occurrence of a V prize in the distribution execution mode triggered by the second small hit result, when the opening/closing execution mode is started, the special display section 429 displays 8 A display corresponding to the round game is performed. Further, when the opening/closing execution mode is generated due to the occurrence of a V prize in the distribution execution mode triggered by the third small hit result, when the opening/closing execution mode is started, the special display section 429 displays 14 A display corresponding to the round game is performed. In the above-mentioned configuration, by performing the turning-off process of the special display unit 429 in step SD817 of the special figure variation start process, it corresponds to the number of round games in the special display unit 429 started when the opening/closing execution mode is started. The display is ended when a new game time is started after the opening/closing execution mode is ended. Then, the special display portion 429 is maintained in the off state until a new opening/closing execution mode occurs.

After that, the value of the special figure special power counter is incremented by 1 (step SD818). Since the value of the special figure special power counter when the special figure fluctuation start process is executed is “0”, the value of the special figure special power counter that is the addition target by adding 1 is It becomes "1" corresponding to step SD706).

<Processing during special map change>
Next, the special figure changing process executed in step SD706 of the special figure special power control process (FIG. 218) will be described.

In the case where the display continuation period of this game time has not elapsed, and when it is the update timing of the display contents of the special view display units 425, 426 which are the execution targets of this game time, Data setting for updating the display contents of the special figure display portions 425 and 426 is performed by referring to the variable display table. As a result, the display contents of the patterns on the special figure display portions 425 and 426, which are the objects of the game play this time, are updated to the display contents in the next order. In the main RAM 65, a first display order counter that is referred to in order to derive the display contents of the picture from the variable display table for the special picture at the time of updating the picture in the first special picture display unit 425. It is provided. Further, the main RAM 65 has a second display order counter which is referred to in order to derive the display contents of the picture from the variable display table for the special picture at the time when the picture is updated in the second special figure display unit 426. It is provided.

The mode at the time of starting the variable display of the pattern on the special figure display portions 425 and 426 and the updating mode of the variable display of the pattern are performed in a fixed mode regardless of the result of the hit/miss determination process and the result of the type determination process. It is carried out in a fixed manner regardless of the contents of the effect for game diversion on the symbol display device 424. For example, when a predetermined number of times of update occur, the display content of the pattern makes one round and the display pattern in which the display order is constant is repeatedly performed, and when the display continuation period of the game time has passed, Regardless of the order in which the display patterns are displayed, the stop result determined at the start of the game is displayed. This makes it possible to simplify the processing configuration for controlling the display of the special figure display units 425 and 426.

On the other hand, when the display continuation period of the game time has elapsed, the information on the stop mode of the picture of the special figure display portions 425, 426 stored in the main RAM 65 at the start of the game time is read and the stop mode of the picture is also read. The special figure display parts 425 and 426, which are the objects of the current game, are displayed and controlled so that. As a result, in the special figure display portions 425 and 426 which are the execution targets of the current game time, the pattern corresponding to the result of the success/failure determination process and the result of the type determination process of the current game time is displayed. The variable display is stopped. Regardless of whether it is in the distribution execution mode or the open/close execution mode, the manner in which the symbols are stopped and displayed in the special map display units 425 and 426 is It is maintained until it is started. Further, the information of the final stop period (for example, 0.5 sec) is set in the timer counter of the main RAM 65. As a result, the measurement of the final stop period is started.

After that, the final stop command is transmitted to the voice emission control device 81. When receiving the final stop command from the main CPU 63, the sound emission control device 81 transmits the final stop command to the display control device 82. When the final stop command is received from the voice emission control device 81, the display control device 82 reads the display pattern table for stopping and displaying the combination of the stop symbols in the current game time over the final stop period. As a result, a combination of stop symbols corresponding to the current game time is stopped and displayed on the symbol display device 424 over the final stop period.

After that, 1 is added to the value of the special figure special power counter. Since the value of the special figure special power counter is "1" when the special figure changing process is executed, the value of the special figure special power counter corresponds to the special figure fixing process (step SD707) by adding 1. It becomes "2".

<Processing during special map confirmation>
Next, referring to the flowchart of FIG. 220, the special figure finalizing process executed in step SD707 of the special figure special electric power control process (FIG. 218) will be described. Note that the processes of step SD901 to step SD915 in the special figure finalization process are executed by using the specific control program and the specific control data in the main CPU 63.

When the final stop period has elapsed and the current game number corresponds to the jackpot result (step SD901 and step SD902: YES), display start processing of the special display unit 429 is executed (step SD903). .. In the display start process of the special display unit 429, when the jackpot result of this time is the 6R jackpot result, data setting for controlling the display of the special display unit 429 so that the display corresponding to the six round games is started. I do. Further, in the display start process of the special display unit 429, in order to control the display of the special display unit 429 so that the display corresponding to the 15 round game is started when the present jackpot result is the 15R jackpot result. Set the data. After that, 3 is added to the value of the special figure special power counter (step SD904). Since the value of the special figure special power counter when the special figure finalizing process is executed is “2”, the value of the special figure special power counter that has been added by adding 3 is the special power start processing (step SD710). ) Corresponds to “5”.

If the final stop period has elapsed and the current game time does not correspond to the jackpot result (step SD901: YES, step SD902: NO), the support flag provided in the main RAM 65 is "1". Is set (step SD905). The support flag is a flag that is set to "1" in the high frequency support mode and becomes "0" in the low frequency support mode. Therefore, in step SD905, it is determined whether the support mode is the high frequency support mode.

When the high-frequency support mode is set and the support flag is set to "1" (step SD905: YES), whether or not the game time ended this time is a game time triggered by the hold information on the second special map side. Is determined (step SD906). When the game time ended this time is a game time triggered by the hold information on the second special figure side (step SD906: YES), the value of the second special figure counter provided in the main side RAM 65 is decremented by 1 and (Step SD907), 1 is subtracted from the value of the total counter provided in the main RAM 65 (step SD908). On the other hand, when the game time ended this time is a game time triggered by the hold information on the first special figure side (step SD906: NO), the value of the first special figure counter provided in the main RAM 65 is decremented by 1. At the same time (step SD909), the sum counter value of the main RAM 65 is decremented by 1 (step SD910). After executing the processing of step SD908 or step SD910, it is determined whether or not the value of any of the first special figure counter, the second special figure counter, and the total counter is "0" (step SD911). If an affirmative decision is made in step SD911, the support flag of the main side RAM 65 is cleared to "0" (step SD912). As a result, the support mode shifts from the high frequency support mode to the low frequency support mode.

As described above, when the open/close execution mode ends, the support mode becomes the high frequency support mode. This high frequency support mode ends and shifts to the low frequency support mode when the number of times of execution of the game times after the end of the opening/closing execution mode reaches the end reference number. The first special figure counter, the second special figure counter, and the total counter are all counters for the main CPU 63 to specify the end reference number. The first special figure counter is a counter for measuring the number of times the game times are executed triggered by the hold information on the first special figure side after the opening/closing execution mode is finished, and the second special figure counter is the opening/closing execution. It is a counter for measuring the number of executions of the game times triggered by the hold information on the second special map side after the mode ends, and the total counter is on the first special map side after the opening/closing execution mode ends. It is a counter for measuring the total number of executions of the game times triggered by the hold information and the game times triggered by the hold information on the second special map side. "100" is set in the first special figure counter and total counter when the open/close execution mode ends, regardless of which type of big hit result or small hit result triggered the occurrence of the open/close execution mode. To be done. On the other hand, the second special figure counter is set to "1" in the opening/closing execution mode triggered by the 6R jackpot result by the pending information on the first special figure side, and the opening/closing execution is triggered by other cases. If the mode is set, "5" is set.

As described above, when the game times triggered by the hold information on the first special map side are executed, the values of the first special map counter and the total counter are decremented by 1, respectively, and the second special map side reserved information. When the game time is triggered by, the values of the second special figure counter and the total counter are each decremented by 1. Then, when the value of any of the first special figure counter, the second special figure counter, and the total counter becomes “0”, the high frequency support mode is shifted to the low frequency support mode. Therefore, in the high-frequency support mode, the opening/closing execution mode ends when the number of game times executed after the opening/closing execution mode ends is 1 or 5 times triggered by the holding information on the second special map side. If the number of executions of the game times triggered by the hold information on the first special map side is 100 times, or the game time is triggered by the hold information on the first special map side after the opening/closing execution mode ends. And it ends when the total number of game times triggered by the hold information on the second special map side is 100 times.

However, in the high frequency support mode, the shooting operation is basically performed so that the game ball flows down the right side area PA3. Therefore, the high-frequency support mode basically ends when the number of game times executed after the opening/closing execution mode ends is one or five times triggered by the hold information on the second special map side. Becomes In addition, when the number of executions of the game times triggered by the holding information on the second special map side after the opening/closing execution mode is ended is one, the ending is the first number after the opening/closing execution mode is ended. 2 The high-frequency support mode ends when the game times triggered by the hold information on the special map side end. In addition, when the number of executions of the game times triggered by the holding information on the second special map side after the end of the opening/closing execution mode is 5 times, the ending is the fifth time after the opening/closing execution mode is ended. The high-frequency support mode ends when the game times triggered by the hold information on the second special map side ends.

If a negative decision is made in step SD905, a negative decision is made in step SD911, or if the processing of step SD912 is executed, it is decided whether or not the current game time corresponds to the small hit result (step SD913). If the current game number does not correspond to the small hit result (step SD913: NO), the value of the special figure special power counter is cleared to "0" (step SD914). As a result, the value of the special figure special electricity counter becomes "0" corresponding to the special figure variation start processing (step SD705). On the other hand, when the game number of this time corresponds to the small hit result (step SD913: YES), the value of the special figure special power counter is incremented by 1 (step SD915). Since the value of the special figure special electric counter when the special figure finalizing process is executed is “2”, the value of the special figure special electric counter that is the addition target by adding 1 is the distribution start processing ( It becomes "3" corresponding to step SD708).

<Process for starting sorting>
Next, the distribution start processing executed in step SD708 of the special figure special power control processing (FIG. 218) will be described.

First, a distribution start command is transmitted to the voice emission control device 81. When receiving the distribution start command from the main CPU 63, the sound emission control device 81 controls the light emission of the display light emitting unit 53 and the sound of the speaker unit 54 so that an effect indicating that the distribution execution mode is being executed is executed. Perform output control. Further, the sound emission control device 81 transmits a distribution start command to the display control device 82. When the display control device 82 receives the distribution start command from the audio emission control device 81, after the display effect indicating that the distribution execution mode has been started is executed, the display indicating that the distribution execution mode is in progress is displayed. Display control of the symbol display device 424 is performed so that the effect is executed.

After that, “10” is set in the distribution prize counter provided in the main RAM 65. The distribution prize winning counter is an opportunity to switch the distribution winning device 415 from the open state to the closed state in relation to the number of game balls entered in the distribution winning device 415 which is in the open state in the distribution execution mode. This is a counter for the main CPU 63 to specify. Also, the process of setting the distribution release period is executed. In the setting process of the distribution opening period, information corresponding to the 10 seconds is stored in the timer counter of the main RAM 65 so that the distribution winning device 415 is maintained in the opened state for 10 seconds which is the distribution opening period. set. Then, in order to open the distribution winning apparatus 415, output of a drive signal to the drive unit 443 for distribution entrance is started.

After that, 1 is added to the value of the special figure special power counter. When the distribution start process is executed, the value of the special map special power counter is "3", so that the value of the special map special power counter corresponds to the distribution process (step SD709) by adding 1. 4”.

<Distribution processing>
Next, the distribution process executed in step SD709 of the special figure special power control process (FIG. 218) will be described with reference to the flowchart of FIG. 221. Note that the processing of steps SE101 to SE118 in the distribution processing is executed using the specific control program and specific control data in the main CPU 63.

First, it is determined whether or not it is time to switch the switching piece 446 of the distribution winning apparatus 415 from the retracted position to the V guiding position (step SE101). When 2 seconds have passed since the distribution winning apparatus 415 was opened, a positive determination is made in step SE101. When an affirmative determination is made in step SE101, a drive signal is output to the switching drive unit 447 so that the switching piece 446 moves from the retracted position to the V guidance position (step SE102). As a result, the switching piece 446 is arranged at the V guiding position, and the game ball that has reached the position of the switching piece 446 is guided to the V winning passage area 445c by the switching piece 446 and detected by the V winning detection sensor 449. ..

When the game ball is detected by the V winning detection sensor 449 of the distribution winning apparatus 415 (step SE103: YES), "1" is set to the V winning flag provided in the main RAM 65 (step SE104). The V prize flag is a flag for the main CPU 63 to specify that the game ball has been detected by the V prize detection sensor 449. Further, the V winning command is transmitted to the voice emission control device 81 (step SE105). When the sound emission control device 81 receives the V winning command from the main CPU 63, the emission control of the display light emitting unit 53 is performed so that the effect corresponding to the detection of the game ball by the V winning detection sensor 449 is executed. The sound output control of the speaker unit 54 is executed. The voice emission control device 81 also transmits a V winning command to the display control device 82. When the display control device 82 receives the V winning command from the voice emission control device 81, the display control device 82 displays the symbol display device 424 so that the display effect indicating that the game ball is detected by the V winning detection sensor 449 is executed. Control.

In the situation where the distribution winning apparatus 415 is in the open state, it is determined whether or not the distribution opening period measured using the timer counter of the main RAM 65 has elapsed (step SE106). When the distribution open period has not elapsed (step SE106: NO), the distribution is determined by determining whether or not the game ball is detected by the count detection sensor 448 or the V prize detection sensor 449 of the distribution winning device 415. It is determined whether or not a prize has been awarded to the winning device 415 (step SE107). When a prize has been paid to the distribution prize device 415 (step SE107: YES), the value of the distribution prize counter of the main RAM 65 is decremented by 1 (step SE108). Then, it is determined whether or not the value of the distribution prize counter after the subtraction of 1 is "0" (step SE109).

If an affirmative decision is made in step SE106 or an affirmative decision is made in step SE109, the closing condition of the distribution-winning device 415 is satisfied, so that the drive signal is output to the drive part 443 for the distribution entrance. Then, the distribution winning apparatus 415 is closed (step SE110). After that, in order to wait for the end of the distribution execution mode until the gaming balls are surely not present in the distribution winning device 415, information corresponding to the waiting period is set in the timer counter of the main RAM 65 (step SE111). .. The waiting period is set as a period longer than the longest period required for the game ball that has entered the distribution winning apparatus 415 to be detected by either the count detection sensor 448 or the V winning detection sensor 449. Specifically, it is set to 4 seconds. By waiting for the end of the distribution execution mode until the waiting period elapses in this way, the gaming ball that entered the distribution winning device 415 immediately before the distribution winning device 415 is closed is temporarily detected as a V winning. When detected by the sensor 449, it can be treated as valid.

When the waiting period measured by the timer counter of the main RAM 65 has elapsed (step SE112: YES), the switching piece 446 is driven to the switching drive unit 447 so as to return from the V guiding position to the retracted position. The signal output is stopped (step SE113). As a result, the switching piece 446 returns to the retracted position.

After that, by determining whether or not the V winning flag of the main RAM 65 is set to "1", it is determined whether or not the game ball is detected by the V winning detection sensor 449 in the current distribution execution mode. (Step SE114). When the V winning flag is set to "1" (step SE114: YES), display start processing of the special display portion 429 is executed (step SE115). In the display start process of the special display unit 429, when the distribution execution mode this time is triggered by the first small hit result, the special display unit 429 is displayed so that the display corresponding to the five round games is started. Set data for control. Further, in the display start processing of the special display unit 429, when the distribution execution mode this time is triggered by the second small hit result, the display corresponding to eight round games is started so that the special display unit 429 is started. Set data for display control. In the display start processing of the special display unit 429, when the distribution execution mode this time is triggered by the third small hit result, the special display unit 429 is started so that the display corresponding to the 14th round game is started. Set data for display control. After that, 1 is added to the value of the special figure special electricity counter (step SE116). When the distribution process is executed, the value of the special figure special power counter is "4", so that the value of the special figure special power counter that has been added by adding 1 is the special power start processing (step SD710). It corresponds to "5". When the affirmative determination is made in step SE114, the V winning flag is cleared to "0".

When "1" is not set in the V winning flag (step SE114: NO), a flag clearing process is executed (step SE117). In the flag clearing process, a flag or the like for specifying the type of the small hit result is cleared to "0". After that, the value of the special map special electric counter is cleared to "0" (step SE118). As a result, the value of the special figure special electricity counter becomes "0" corresponding to the special figure variation start processing (step SD705).

<Special train start processing>
Next, the special electric power start processing executed in step SD710 of the special electric power control processing (FIG. 218) will be described.

In the special electric power start process, before the start of the opening period, the measurement of the opening period (for example, 4 seconds) is started and the opening command is transmitted to the voice emission control device 81. When receiving the opening command, the sound emission control device 81 executes the emission control of the display emission section 53 and the sound output control of the speaker section 54 so that the opening effect is executed. Further, the sound emission control device 81 transmits an opening command to the display control device 82. When the display control device 82 receives the opening command, the display control device 82 executes the display control of the symbol display device 424 so that the opening effect is executed.

In the special electric power starting process, when the opening period has elapsed, information corresponding to the number of times the round game is executed in the opening/closing execution mode this time is set in the round counter provided in the main RAM 65. The round counter is a counter for specifying the number of remaining round games in the main CPU 63 in the open/close execution mode, and the value of the round counter is decremented by 1 each time a round game is executed. Further, the timer counter of the main RAM 65 is set with information (specifically 29 seconds) of the open duration of the round game, and the special prize winning device 416 in one round game is set in the prize counter provided in the main RAM 65. The information (specifically, "10") corresponding to the upper limit number of winning prizes is set. Then, the special electric open setting process is executed. In the opening setting process, the output of the drive signal to the drive unit 416c for special electric power is started so that the special electric prize winning device 416 is in the open state. After that, 1 is added to the value of the special figure special power counter. As a result, the value of the special figure special electric power counter becomes "6" corresponding to the special electric power open processing (step SD711).

<Processing during opening of special train>
Next, the special electric power releasing control processing executed in step SD711 of the special electric power control processing (FIG. 218) will be described.

In the special electric open process, the closing setting process is executed when the opening continuation period of the special electric prize winning device 416 has elapsed or when the special electric prize winning device 416 has won the upper limit winning number of game balls. In the closing setting process, the output of the drive signal to the drive unit 416c for special electricity is stopped so that the special electricity winning device 416 is closed. Then, the value of the round counter of the main RAM 65 is decremented by 1.

When the value of the round counter after subtracting 1 is not "0", information (specifically, 2 seconds) corresponding to the closing duration is set in the timer counter of the main RAM 65. After that, 1 is added to the value of the special figure special power counter. As a result, the value of the special map special electric power counter becomes "7" corresponding to the special electric power closing process (step SD712).

When the value of the round counter after subtracting 1 is “0”, information (specifically, 10 seconds) corresponding to the ending period is set in the timer counter of the main RAM 65. Further, the ending command is transmitted to the sound emission control device 81. When the sound emission control device 81 receives the ending command, the sound emission control device 81 executes the light emission control of the display light emitting unit 53 and the sound output control of the speaker unit 54 so that the ending effect is executed. Further, the audio emission control device 81 transmits an ending command to the display control device 82. When receiving the ending command, the display control device 82 executes the display control of the symbol display device 424 so that the ending effect is executed. After that, the value of the special map special electric counter is incremented by 2. As a result, the value of the special map/special electric counter becomes “8” corresponding to the special electric power termination processing (step SD713).

<Processing during closing of special train>
Next, the special electric power closing control processing executed in step SD712 of the special electric power control processing (FIG. 218) will be described.

If the closing continuation period has elapsed, the timer counter of the main RAM 65 is set with information on the opening continuation period of the round game (specifically, 29 seconds), and the winning counter of the main RAM 65 is used for one round game. The information (specifically, "10") corresponding to the upper limit winning number to the special electric prize winning device 416 in is set. Then, the special electric winning device 416 is opened by executing the special electric open setting process. After that, 1 is subtracted from the value of the special figure special power counter. As a result, the value of the special figure special electric power counter becomes "6" corresponding to the special electric power open processing (step SD711).

<Tokuden termination processing>
Next, the special electric power ending processing executed in step SD713 of the special electric power control processing (FIG. 218) will be described with reference to the flowchart of FIG. 222. In addition, the processing of step SE201 to step SE209 in the special electric power ending processing is executed by using the program for specific control and the data for specific control in the main CPU 63.

When the ending period has elapsed (step SE201: YES), "100" is set to the total counter of the main RAM 65 (step SE202), and "100" is set to the first special figure counter of the main RAM 65. Set (step SE203). Then, it is determined whether or not the opening/closing execution mode this time is triggered by the hold information on the second special figure side (step SE204). Further, when the opening/closing execution mode this time is triggered by the hold information on the first special map side (step SE204: NO), it is determined whether or not the opening/closing execution mode this time is triggered by the 15R jackpot result (step S204). SE205). When affirmative determination is made in step SE204 or step SE205, "5" is set to the second special figure counter of the main RAM 65 (step SE206), and negative determination is made in both step SE204 and step SE205. Is set to "1" in the second special figure counter of the main RAM 65 (step SE207). By the processing in steps SE202 to SE207, the termination condition of the high frequency support mode after the opening/closing execution mode is terminated is set.

When the process of step SE206 or step SE207 is executed, "1" is set to the support flag of the main RAM 65 (step SE208). As a result, the support mode after the open/close execution mode has ended becomes the high-frequency support mode. After that, the value of the special map special electric counter is cleared to "0" (step SE209). As a result, the value of the special figure special electricity counter becomes "0" corresponding to the special figure variation start processing (step SD705).

<Notification that setting related processing is being executed>
Next, the setting confirmation process (step SC213) or the set value update process (step SC216) is executed in the main process (FIG. 185) that is started when the supply of operating power to the main CPU 63 is started. A configuration for notifying that there is a situation will be described.

FIG. 223 is an explanatory diagram for explaining each area provided in the clear target area 371 of the work area 221 for specific control.

In the clear target area 371, as in the 56th embodiment, the first display data buffer 271, the second display data buffer 272, the third display data buffer 273, the fourth display data buffer 274 and the fifth display data buffer 275. Is provided. In addition to the first to fifth display data buffers 271-275, the clear target area 371 is provided with a sixth display data buffer 471, a seventh display data buffer 472, and an eighth display data buffer 473.

The first display data buffer 271 stores display data for causing the first special figure display unit 425 to perform a predetermined display. In step SD816 of the special figure variation start processing (FIG. 219), the processing for starting the variable display of the picture is executed in the first special figure display unit 425, whereby the display control in the first timer interrupt processing (FIG. 133). In the process (step S8915), the display data corresponding to the display at the start of fluctuation of the first special figure display unit 425 is set in the first display data buffer 271. Further, the processing for updating the display content of the first special figure display unit 425 is executed in the special figure changing process (step SD706) in the special figure special power control process (FIG. 218), whereby the first timer interrupt process is performed. In the display control process (step S8915) in (FIG. 133), display data for advancing the variable display of the pattern on the first special figure display unit 425 is set in the first display data buffer 271. In addition, in the special figure special electric power control processing (FIG. 218), during the special figure changing process (step SD706), the contents displayed on the first special figure display portion 425 are changed to the winning/non-judgment process (step SD803) and the big hit time. By executing the processing for setting the display content corresponding to the processing result of the type determination processing (step SD805), the first special figure display is performed by the display control processing (step S8915) in the first timer interrupt processing (FIG. 133). Display data for causing the unit 425 to perform display corresponding to the result of the current game is set in the first display data buffer 271. The display data set in this case is the display data selected in step SD807 or step SD812 of the special figure variation start processing (FIG. 219) at the start of the current game time. In addition, the display data set in this case is stored and held in the first display data buffer 271 until the first special figure display unit 425 is in a situation to start a new game time. A first display circuit 261 is provided so as to correspond to the first special figure display unit 425, and the display data stored in the first display data buffer 271 is supplied to the first display circuit 261 to display the display. A display corresponding to the data is displayed on the first special figure display unit 425.

The second display data buffer 272 stores display data for causing the first special figure reservation display unit 427 to perform a predetermined display. When the pending information on the first special drawing side is newly stored in the first special drawing holding area 452 in the holding information acquisition processing (step SD701) in the special drawing special power control processing (FIG. 218), the first timer In the display control process (step S8915) in the interrupt process (FIG. 133), the display data corresponding to the number of the holding information on the first special figure side stored in the first special figure holding area 452 after the storage is the second. It is set in the display data buffer 272. Further, in the data setting process (step SD802) in the special figure variation start process (FIG. 219), when the hold information on the first special figure side is exhausted as an opportunity to execute the game, the first timer interrupt process (FIG. In the display control process (step S8915) in 133), the display data corresponding to the number of the holding information on the first special figure side stored in the first special figure holding area 452 after the digestion is the second display data buffer 272. Is set to. A second display circuit 262 is provided in correspondence with the first special figure reservation display unit 427, and the display data stored in the second display data buffer 272 is supplied to the second display circuit 262, thereby The display corresponding to the display data is displayed on the first special figure reservation display unit 427.

The third display data buffer 273 stores display data for causing the universal figure display unit 423a to perform a predetermined display. In the universal figure variation start processing (step SD606) of the universal figure universal communication control processing (FIG. 217), the processing for starting the variable display of the pattern on the universal figure display portion 423a is executed, whereby the first timer interrupt processing ( In the display control process (step S8915) in FIG. 133), the display data corresponding to the display at the start of the fluctuation of the universal figure display unit 423a is set in the third display data buffer 273. Further, the processing for updating the display content of the universal figure display unit 423a is executed in the universal figure changing process (step SD607) of the universal figure universal communication control process (FIG. 217), whereby the first timer interrupt process ( In the display control process (step S8915) in FIG. 133), the display data for advancing the variable display of the picture on the universal figure display unit 423a is set in the third display data buffer 273. In addition, the display content of the public figure display unit 423a is changed to the display content corresponding to the result of the guidance state lottery in the current variable display time in the public figure changing process (step SD607) of the general figure/general electric control process (FIG. 217). In order to cause the public figure display unit 423a to perform the display corresponding to the result of the variable display this time in the display control processing (step S8915) in the first timer interrupt processing (FIG. 133) by executing the processing for Display data is set in the third display data buffer 273. The display data set in this case is stored and held in the third display data buffer 273 until a situation in which a new variable display time is started on the universal figure display unit 423a is reached. A third display circuit 263 is provided corresponding to the universal figure display unit 423a, and the display data stored in the third display data buffer 273 is supplied to the third display circuit 263, whereby the display data is changed. Corresponding display is performed on the public figure display unit 423a.

The fourth display data buffer 274 stores display data for causing the universal figure reservation display unit 423b to perform a predetermined display. When the universal figure holding information is newly stored in the universal figure holding area 455 in the universal figure holding information acquisition process (step SD601) of the universal figure universal communication control process (FIG. 217), the first In the display control process (step S8915) in the timer interrupt process (FIG. 133), the display data corresponding to the number of reservation information on the universal figure side stored in the universal figure reservation area 455 after the storage is the fourth display data buffer. 274 is set. Further, in the case of the universal figure fluctuation start processing (step SD606) of the universal figure universal communication control processing (FIG. 217), when the pending information on the universal figure side is consumed as an execution trigger of the variable display time of the universal figure display unit 423a, In the display control process (step S8915) in the first timer interrupt process (FIG. 133), the display data corresponding to the number of reservation information on the universal figure side stored in the universal figure reservation area 455 after the digestion is the fourth. It is set in the display data buffer 274. A fourth display circuit 264 is provided so as to correspond to the universal figure reservation display unit 423b, and the display data stored in the fourth display data buffer 274 is supplied to the fourth display circuit 264 to cause the display data to be displayed. Is displayed on the universal figure hold display section 423b.

The fifth display data buffer 275 stores display data for causing the first to fourth notification display devices 201 to 204 to perform a predetermined display. The setting of the display data in the fifth display data buffer 275 is executed in step SE303, step SE307, and step SE310 in the second timer interrupt process (FIG. 224) described later. A fifth display circuit 265 is provided corresponding to the first to fourth notification display devices 201 to 204, and the display data stored in the fifth display data buffer 275 is supplied to the fifth display circuit 265. By doing so, the display corresponding to the display data is performed on the first to fourth notification display devices 201 to 204.

The sixth display data buffer 471 stores display data for causing the second special figure display unit 426 to perform a predetermined display. In step SD816 of the special figure variation start processing (FIG. 219), the processing for starting the variable display of the picture is executed in the second special figure display unit 426, whereby the display control in the first timer interrupt processing (FIG. 133) is performed. In the process (step S8915), the display data corresponding to the display at the start of variation of the second special figure display unit 426 is set in the sixth display data buffer 471. Further, the processing for updating the display content of the second special figure display portion 426 is executed in the special figure changing process (step SD706) in the special figure special power control process (FIG. 218), whereby the first timer interrupt process In the display control process (step S8915) in (FIG. 133), display data for advancing the variable display of the pattern on the second special figure display unit 426 is set in the sixth display data buffer 471. In addition, during the special figure changing process (step SD706) in the special figure special electric control process (FIG. 218), the display content of the second special figure display portion 426 is changed to the hit determination process (step SD803) in the current game time, Display control in the first timer interrupt process (FIG. 133) by executing the process for setting the display content corresponding to the process result of the type determination process (step SD805) and the type determination process at the time of small hit (step SD809) In the process (step S8915), display data for causing the second special figure display unit 426 to perform display corresponding to the result of the current game time is set in the sixth display data buffer 471. The display data set in this case becomes the display data selected in step SD807, step SD811 or step SD812 of the special figure variation start processing (FIG. 219) at the start of the current game time. Further, the display data set in this case is stored and held in the sixth display data buffer 471 until the second special figure display unit 426 is in a situation to start a new game time. A sixth display circuit is provided corresponding to the second special figure display unit 426, and the display data stored in the sixth display data buffer 471 is supplied to the sixth display circuit, whereby the display data is displayed. Corresponding display is performed on the second special figure display unit 426.

The seventh display data buffer 472 stores display data for causing the second special figure reservation display unit 428 to perform a predetermined display. If the hold information on the second special figure side is newly stored in the second special figure holding area 453 in the holding information acquisition processing (step SD701) in the special drawing special electric control processing (FIG. 218), the first timer In the display control process (step S8915) in the interrupt process (FIG. 133), the display data corresponding to the number of the holding information on the second special figure side stored in the second special figure holding area 453 after the storage is the seventh. It is set in the display data buffer 472. Further, in the data setting process (step SD802) in the special figure fluctuation start process (FIG. 219), when the hold information on the second special figure side is exhausted as an opportunity to execute the game, the first timer interrupt process (FIG. In the display control process (step S8915) in 133), the display data corresponding to the number of the holding information on the second special figure side stored in the second special figure holding area 453 after the digestion is the seventh display data buffer 472. Is set to. A seventh display circuit is provided corresponding to the second special figure reservation display unit 428, and the display data stored in the seventh display data buffer 472 is supplied to the seventh display circuit to cause the display data to be displayed. Is displayed on the second special figure reservation display section 428.

The eighth display data buffer 473 stores display data for causing the special display unit 429 to perform a predetermined display. When the information on the number of round games is set in the display start processing (step SD903) of the special display unit 429 in the special figure finalization processing (FIG. 220) in the game times corresponding to the jackpot result, the first timer interrupt In the display control process (step S8915) in the process (FIG. 133), display data corresponding to the information about the number of round games is stored in the eighth display data buffer 473. Further, when the information on the number of round games is set in the display start processing (step SE115) of the special display unit 429 in the distribution processing (FIG. 221) by entering the distribution execution mode, the first timer In the display control process (step S8915) in the interrupt process (FIG. 133), the display data corresponding to the information about the number of round games is stored in the eighth display data buffer 473. Further, when the turning off process (step SD817) of the special display unit 429 is executed in the special figure variation start process (FIG. 219), the display control process (step S8915) in the first timer interrupt process (FIG. 133) is executed. Then, the display data in the eighth display data buffer 473 is cleared to "0". An eighth display circuit is provided corresponding to the special display section 429, and the display data stored in the eighth display data buffer 473 is supplied to the eighth display circuit to display the display data corresponding to the display data. Is displayed on the special display portion 429.

Since the clear target area 371 includes the first to eighth display data buffers 271 to 275 and 471 to 473, the first RAM clear process (step SC218) or the set value update process (step) of the main process (FIG. 185) is performed. When the second RAM clearing process of SC216) is executed, the display data set in the first to eighth display data buffers 271 to 275 and 471 to 473 is cleared to "0". The clear target area 371 includes an area for special figure special power control and an area for general/universal power control other than the first to eighth display data buffers 271 to 275 and 471 to 473. Therefore, when the first RAM clear process or the second RAM clear process is executed, the support mode becomes the low frequency support mode regardless of the support mode immediately before the supply of the operating power to the pachinko machine 10 is stopped. In addition, the game times are not being executed, the opening/closing execution mode is not being executed, and the general-purpose display unit 423a is not being variably displayed, and the guiding unit 432 of the second operating unit 413 is The situation is in a non-induced state. Further, the setting update display flag and the setting confirmation display flag provided in the specific control work area 221 are cleared to "0", and the setting update area 342 provided to the specific control work area 221 is cleared to "0". To be done. Further, the stack area 222 for specific control is cleared to “0” and the initial setting is executed. Also, after the various registers of the main CPU 63 are cleared to "0", the initial setting is executed.

FIG. 224 is a flowchart showing the second timer interrupt processing executed by the main CPU 63. The processing of steps SE301 to SE317 in the second timer interrupt processing is executed by using the program for specific control and the data for specific control in the main CPU 63. The second timer interrupt process is interrupted when the setting confirmation process (step SC213) of the main process (FIG. 185) is started and the setting confirmation process (step SC213) is ended. Is prohibited. Further, the second timer interrupt process is interrupted when the set value update process (step SC216) of the main process (FIG. 185) is started and the set value update process (step SC216) is ended. Is prohibited. Also, the second timer interrupt process is interrupted from the setting of the interrupt permission in step SC230 of the main process (FIG. 185) to the setting of the interrupt prohibition in step SC227 of the main process (FIG. 185). Is allowed. The same applies to the first timer interrupt processing (FIG. 133).

First, in order to prohibit the occurrence of the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 224), interrupt prohibition is set (step SE301). Since the generation of the first timer interrupt process (FIG. 133) is prohibited, the first timer interrupt process (FIG. 133) interrupts the second timer interrupt process (FIG. 224) even if the first interrupt period has elapsed. It is possible to prevent it from being started with. Further, since the generation of the second timer interrupt process (FIG. 224) is prohibited, even if the second interrupt cycle elapses during the execution of the second timer interrupt process (FIG. 224), the second timer interrupt process It is possible to prevent the processing (FIG. 224) from being activated in duplicate.

Then, it is determined whether or not "1" is set in the setting update display flag in the work area 221 for specific control (step SE302). The setting update display flag is a flag for the main CPU 63 to specify whether or not the setting value update processing (step SC216) is being executed by the main CPU 63. Similar to the 56th embodiment, the second timer interrupt process (FIG. 224) is interrupted and activated even when the set value update process (step SC216) is being executed. If an affirmative decision is made in step SE302, a setting process for the fifth display data buffer 275 during the setting update is executed (step SE303). In the setting process, similarly to the 33rd embodiment, a display indicating that the setting values of the pachinko machine 10 are being updated on the first to fourth notification display devices 201 to 204 and the pachinko machine 10 are displayed. The display data for displaying the current set value of is set in the fifth display data buffer 275. As a result, a display indicating that the setting value of the pachinko machine 10 is being updated and a display indicating the current setting value of the pachinko machine 10 are performed on the first to fourth notification display devices 201 to 204. .. This display is continued while the set value updating process (step SC216) is being executed.

After that, the setting process for the first display data buffer 271 during the setting update is executed (step SE304). FIG. 225(a) is a flowchart showing the setting process for the first display data buffer 271 during the setting update. The processing of steps SE401 to SE405 in the setting processing for the first display data buffer 271 during the setting update is executed using the specific control program and the specific control data in the main CPU 63.

In the setting process, in order to perform the variable display of the pattern as in the case where the game number is being executed on the first special figure display portion 425 in the situation where the set value updating process (step SC216) is being executed. The process of is executed. Further, in the setting process, in order to cause the first special figure display unit 425 to perform the variable display of the pattern, the special figure change display table and the special figure change display table used in the special figure changing process (step SD706). 1 Display order counter is used.

Specifically, first, it is determined whether or not this time is the update timing of the display content of the first special view display unit 425 (step SE401). The cycle of updating the display content of the picture on the first special figure display unit 425 is the same as the cycle of updating the display content of the picture on the first special figure display unit 425 in the game. When it is the display content update timing (step SE401: YES), the value of the first display order counter of the main RAM 65 is incremented by 1 (step SE402). Then, when the value of the first display order counter after adding 1 exceeds the maximum value (for example, "20") (step SE403: YES), the value of the first display order counter is cleared to "0" ( Step SE404). As described above, the first display order counter is a counter for specifying the display content of the pattern to be derived from the variable display table for the special figure when the pattern update timing comes in the first special figure display unit 425. ..

If a negative decision is made in step E401, a negative decision is made in step SE403, or if the process of step SE404 is executed, the display contents of the pattern corresponding to the current value of the first display order counter are used for special drawing. The display data corresponding to the display contents of the derived picture is set in the first display data buffer 271 (step SE405). As a result, the pattern corresponding to the display data is displayed on the first special figure display unit 425.

With the above configuration, in the situation where the setting value update processing (step SC216) is being executed, the display order is a fixed order, as in the case where the game times are being executed on the first special figure display unit 425. The variable display of the design according to a certain display pattern is repeated on the first special figure display unit 425. In this case, the variable display table for the special figure and the first display order counter, which are used to perform the variable display of the design, are used when the game number is executed in the first special figure display unit 425. It is something. As a result, while suppressing the increase in the required storage capacity, it is possible to cause the first special figure display unit 425 to perform the variable display of the pattern in the situation where the setting value update processing (step SC216) is being executed. Become.

Returning to the explanation of the second timer interrupt process (FIG. 224), after executing the setting process (step SE304) for the first display data buffer 271 during the setting update, the setting for the eighth display data buffer 473 during the setting update is performed. A setting process is executed (step SE305). In the setting process, display data for causing the special display unit 429 to perform a predetermined display is set in the eighth display data buffer 473. Specifically, the display setting corresponding to the number of executions of the round game when the 15R jackpot result is obtained in the display starting process (step SD903) of the special display unit 429 in the special figure finalizing process (FIG. 220) is performed. In this case, the same display data as the display data set in the eighth display data buffer 473 is set in the eighth display data buffer 473. As a result, in the situation where the set value update process (step SC216) is being executed, not only the variable display of the pattern is performed on the first special figure display unit 425 as in the case of the game, but also the special display unit 429. In the same manner as when the 15R jackpot result is obtained, a display corresponding to the fact that the number of round games executed is 15 is displayed.

The display data set in the first display data buffer 271 in step SE304 and the display data set in the eighth display data buffer 473 in step SE305 are executed when the set value updating process (step SC216) ends. In the second RAM clearing process (step SB313), "0" is cleared. As a result, when the set value update process (step SC216) is completed, a variable display of the pattern on the first special figure display unit 425 and a display corresponding to the number of times of executing the round game on the special display unit 429 is 15 times. Can be ended. After that, the display start processing (FIG. 191) is executed in step SC226 of the main processing (FIG. 185), whereby the initial display data for special drawing is set in the first display data buffer 271. As a result, similarly to the 56th embodiment, the initial display is started on the first special figure display portion 425. On the other hand, the special display unit 429 is kept in the off state until the next opening/closing execution mode is started.

The display data set in the eighth display data buffer 473 in step SE305 is not limited to the configuration that is the display data for performing the display corresponding to the number of times the round game is executed 15 times. For example, as in the case of the 6R jackpot result, the display data may be display data corresponding to the fact that the round game is executed six times, as in the case of the 1st jackpot result. The display data may be display data for performing a display corresponding to the number of times the round game is executed five times, and the number of times the round game is executed is eight as in the case of the second small hit result. It may be display data for performing a display corresponding to a certain thing, and in order to perform a display corresponding to the number of times of executing the round game being 14 as in the case of the third small hit result. May be display data. Even in these cases, the set value update process (step SC216) is executed by using the display data used to cause the special display unit 429 to perform a predetermined display when the open/close execution mode occurs. It is possible to give a notification on the special display portion 429 indicating that the situation is present.

When a negative determination is made in step SE302, it is determined whether the setting confirmation display flag in the specific control work area 221 is set to "1" (step SE306). The setting confirmation display flag is a flag for the main CPU 63 to specify whether or not the setting confirmation process (step SC213) is being executed by the main CPU 63. Similar to the 56th embodiment, the second timer interrupt process (FIG. 224) is activated by interruption even when the setting confirmation process (step SC213) is being executed. When an affirmative decision is made in step SE306, the setting process for the fifth display data buffer 275 during the setting confirmation is executed (step SE307). In the setting process, similarly to the 33rd embodiment, a display indicating that the setting value of the pachinko machine 10 is being confirmed on the first to fourth display devices 201 to 204 and the pachinko machine 10 are displayed. The display data for displaying the current set value of is set in the fifth display data buffer 275. As a result, a display indicating that the setting value of the pachinko machine 10 is being confirmed on the first to fourth notification display devices 201 to 204 and a display indicating the current setting value of the pachinko machine 10 are performed. .. This display is continued while the setting confirmation process (step SC213) is being executed.

After that, the setting process for the sixth display data buffer 471 during the setting confirmation is executed (step SE308). FIG. 225(b) is a flowchart showing the setting process for the sixth display data buffer 471 during the setting confirmation. Note that the processing of steps SE501 to SE505 in the setting processing for the sixth display data buffer 471 during the setting confirmation is executed using the specific control program and the specific control data in the main CPU 63.

In the setting process, in order to perform the variable display of the pattern in the same manner as when the game times are being executed on the second special figure display unit 426 in the situation where the setting confirmation process (step SC213) is being executed. The process of is executed. Further, in the setting processing, in order to cause the second special figure display unit 426 to perform the variable display of the design, the special figure change display table and the special figure change display table used in the special figure changing process (step SD706). 2 Use a display order counter.

Specifically, first, it is determined whether or not this time is the update timing of the display content of the second special view display unit 426 (step SE501). The cycle of updating the display content of the picture on the second special figure display unit 426 is the same as the cycle of updating the display content of the picture on the second special figure display unit 426 in the game. If it is the display content update timing (step SE501: YES), the value of the second display order counter of the main RAM 65 is incremented by 1 (step SE502). When the value of the second display order counter after adding 1 exceeds the maximum value (for example, "20") (step SE503: YES), the value of the second display order counter is cleared to "0" ( Step SE504). As described above, the second display order counter is a counter for specifying the display contents of the pattern to be derived from the variable display table for the special figure when the timing of updating the pattern in the second special figure display unit 426 is reached. ..

If a negative decision is made in step E501, a negative decision is made in step SE503, or if the process of step SE504 is executed, the display contents of the picture corresponding to the current value of the second display order counter are used for special drawing. The display data corresponding to the display contents of the derived picture is set in the sixth display data buffer 471 (step SE505). As a result, the pattern corresponding to the display data is displayed on the second special figure display unit 426.

With the above configuration, in the situation where the setting confirmation process (step SC213) is being executed, the display order is a fixed order as in the case where the game time is being executed on the second special figure display unit 426. The variable display of the design according to a certain display pattern is repeated on the second special figure display unit 426. In this case, the variable display table for the special figure and the second display order counter, which are used to perform the variable display of the design, are used when the game number is executed in the second special figure display unit 426. It is something. As a result, it is possible to cause the second special figure display unit 426 to perform variable display of the pattern while the setting confirmation process (step SC213) is being executed while suppressing an increase in the required storage capacity. Become.

Returning to the explanation of the second timer interrupt processing (FIG. 224), after executing the setting processing (step SE308) for the sixth display data buffer 471 during the setting confirmation, the setting for the eighth display data buffer 473 during the setting confirmation is performed. A setting process is executed (step SE309). In the setting process, display data for causing the special display unit 429 to perform a predetermined display is set in the eighth display data buffer 473. Specifically, the display setting corresponding to the number of executions of the round game when the 6R jackpot result is obtained in the display starting process (step SD903) of the special display unit 429 in the special figure finalizing process (FIG. 220) is performed. In this case, the same display data as the display data set in the eighth display data buffer 473 is set in the eighth display data buffer 473. As a result, in the situation where the setting confirmation process (step SC213) is being executed, not only the variable display of the symbols is displayed on the second special figure display unit 426 as in the case of the game, but also the special display unit 429. In the same manner as when the 6R jackpot result is obtained, a display corresponding to the fact that the number of round games executed is 6 is displayed. The display content of the special display unit 429 is different from the display content of the special display unit 429 in the situation where the set value updating process (step SC216) is being executed.

The display data set in the sixth display data buffer 471 in step SE308 and the display data set in the eighth display data buffer 473 in step SE309 are set to "0" when the setting confirmation process (step SC213) ends. It will be cleared. As a result, when the setting confirmation process (step SC213) is completed, the variable display of the pattern on the second special figure display unit 426 and the display corresponding to the number of times the round game is executed on the special display unit 429 are six times. Can be ended. Thereafter, the display start process (FIG. 191) is executed in step SC226 of the main process (FIG. 185), whereby the initial display data for special drawing is set in the sixth display data buffer 471. As a result, the initial display is started on the second special figure display unit 426. On the other hand, the special display unit 429 is kept in the off state until the next opening/closing execution mode is started.

Note that the display data set in the eighth display data buffer 473 in step SE309 is not limited to the configuration that is the display data for performing the display corresponding to the number of round game executions being six. For example, as in the case of the 15R jackpot result, the display data may be display data corresponding to the fact that the round game is executed 15 times, and the same as the case of the 1st jackpot result. The display data may be display data for performing a display corresponding to the number of times the round game is executed five times, and the number of times the round game is executed is eight as in the case of the second small hit result. It may be display data for performing a display corresponding to a certain thing, and in order to perform a display corresponding to the number of times of executing the round game being 14 as in the case of the third small hit result. May be display data. Even in these cases, the setting confirmation process (step SC213) is executed using the display data used to cause the special display unit 429 to perform a predetermined display when the open/close execution mode occurs. It is possible to give a notification indicating that the user is present on the special display unit 429.

When a negative determination is made in step SE306, the process of step SE310 is executed. The processing content of step SE310 is the same as step S8406 of the second timer interrupt processing (FIG. 123) in the thirty-third embodiment.

When the process of step SE305, step SE309, or step SE310 is executed, the transmission state of the signal through the type data signal line LN1 and the type clock signal line LN2 is set to the OFF state, as in the 33rd embodiment described above (step SE311), the transmission state of the signal through the display data signal line LN3 and the display clock signal line LN4 is turned off (step SE312). After that, the type counter provided in the specific control work area 221 is updated (step SE313).

The type counter is a counter for the main CPU 63 to specify the display data transmission target among the first to eighth display data buffers 271 to 275 and 471 to 473 in the current processing time of the second timer interrupt processing. .. When the value of the type counter is "1", the display data of the first display data buffer 271 is the transmission target, and when the value of the type counter is "2", the display data of the second display data buffer 272 is the transmission target. When the value of the type counter is “3”, the display data of the third display data buffer 273 is the transmission target, and when the value of the type counter is “4”, the display data of the fourth display data buffer 274 is When the value of the type counter is “5”, the display data of the fifth display data buffer 275 is the target of transmission, and when the value of the type counter is “6”, the display of the sixth display data buffer 471 is displayed. If the data is the transmission target and the value of the type counter is “7”, the display data of the seventh display data buffer 472 is the transmission target and the value of the type counter is “8”, the eighth display data buffer 473. The display data of is the transmission target. In the type counter updating process, the value of the type counter is incremented by 1, and if the value of the type counter after adding 1 exceeds the upper limit value “8”, the value of the type counter is set to “1”. .. As a result, the transmission target of the display data in the first to eighth display data buffers 271 to 275 and 471 to 473 is sequentially changed for each processing time of the second timer interrupt processing.

After that, the type data corresponding to the value of the type counter is read from the main ROM 64 (step SE314). Specifically, when the value of the type counter is "1", the type data corresponding to the first display circuit 261 is read from the main ROM 64, and when the value of the type counter is "2", the second type data is read. The type data corresponding to the display circuit 262 is read from the main ROM 64, and when the type counter value is “3”, the type data corresponding to the third display circuit 263 is read from the main ROM 64 and the type counter value is When it is “4”, the type data corresponding to the fourth display circuit 264 is read from the main ROM 64, and when the value of the type counter is “5”, the type data corresponding to the fifth display circuit 265 is mainly read. When the type counter value is "6" read from the side ROM 64, the type data corresponding to the sixth display circuit is read from the main side ROM 64, and when the type counter value is "7", the seventh display is performed. The type data corresponding to the circuit is read from the main ROM 64, and when the value of the type counter is "8", the type data corresponding to the eighth display circuit is read from the main ROM 64.

Then, the display data is read from the display data buffers 271 to 275 and 471 to 473 corresponding to the value of the type counter (step SE315). Specifically, when the value of the type counter is "1", the display data is read from the first display data buffer 271, and when the value of the type counter is "2", the second display data buffer 272 is read. When the display data is read and the value of the type counter is “3”, the display data is read from the third display data buffer 273, and when the value of the type counter is “4”, the fourth display data buffer 274 is read. When the display data is read and the value of the type counter is “5”, the display data is read from the fifth display data buffer 275, and when the value of the type counter is “6”, the sixth display data buffer 471 is read. When the display data is read and the value of the type counter is “7”, the display data is read from the seventh display data buffer 472, and when the value of the type counter is “8”, the eighth display data buffer 473 is read. Read the display data.

After that, transmission processing of various signals is executed (step SE316). In the transmission process, signals are output to the type data signal line LN1 and the type clock signal line LN2 so that the type data read in step SE314 is transmitted to the display IC 266. Further, in the transmission process, signals are output to the display data signal line LN3 and the display clock signal line LN4 so that the display data read in step SE315 is transmitted to the display IC 266.

After that, the interrupt permission is set to permit the generation of the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 224) (step SE317).

Next, how the display contents of the first special figure display unit 425, the second special figure display unit 426, and the special display unit 429 change according to the state of the pachinko machine 10 will be described with reference to the time chart of FIG. 226. .. 226(a) shows the period during which the setting value update process (step SC216) is being executed, FIG. 226(b) shows the period during which the setting confirmation process (step SC213) is being executed, and FIG. ) Indicates a period during which the variable display of the pattern is being executed on the first special figure display unit 425, and FIG. 226(d) indicates a period during which the predetermined pattern is stopped and displayed on the first special figure display unit 425. 226(e) shows a period during which the variable display of the pattern is being executed on the second special figure display unit 426, and FIG. 226(f) is the predetermined special pattern is stopped on the second special figure display unit 426. The displayed period is shown, and FIG. 226(g) shows the period during which a predetermined display is performed on the special display portion 429.

First, a situation where the setting value updating process (step SC216) and the setting confirmation process (step SC213) are not executed will be described.

At the timing of t1, the game time is started with the holding information on the first special figure side as a trigger, so that the variable display of the pattern starts on the first special figure display unit 425 as shown in FIG. 226(c). To be done. When the display continuation period of the game time elapses at the timing of t2, the variable display of the pattern on the first special figure display portion 425 is ended as shown in FIGS. 226(c) and 226(d), The display of the pattern corresponding to the result of the hit/miss determination processing and the type determination processing in the game time is started on the first special figure display unit 425. In this case, the 15R jackpot result is selected in the game cycle. Therefore, at the timing of t2, the stop display of the pattern corresponding to the 15R jackpot result is started on the first special figure display unit 425.

After that, at the timing of t3, the final stop period of the stop display of the pattern elapses, the game time corresponding to the jackpot result is ended, and the opening/closing execution mode is started. In this case, at the timing of t3, as shown in FIG. 226(g), the display corresponding to the number of times the round game is executed is 15 is started in the special display portion 429. The special display unit 429 is in the off state until the timing of t3.

After that, at the timing of t4, the opening/closing execution mode ends and the variable display of the pattern is started on the second special figure display unit 426 as shown in FIG. 226(e). In this case, the special display portion 429 is turned off at the timing of t4 as shown in FIG. 226(g). Then, as the display continuation period of the game time elapses at the timing of t5, as shown in FIGS. 226(e) and 226(f), the variable display of the pattern on the second special figure display unit 426 is finished, The display of the pattern corresponding to the result of the hit/miss determination processing and the type determination processing in the game time is started in the second special figure display unit 426. In this case, the first small hit result is selected in the game time. Therefore, at the timing of t5, the stop display of the pattern corresponding to the first small hit result is started on the second special figure display portion 426.

After that, the distribution execution mode is started when the final stop period of the stop display of the pattern elapses, and the distribution execution mode ends at the timing of t6. Since the V winning is generated in the distribution execution mode, the opening/closing execution mode is started at the timing of t6. In this case, at the timing of t6, as shown in FIG. 226(g), the display corresponding to the number of times the round game is executed is 5 is started in the special display portion 429. The special display portion 429 is in the off state until the timing of t6. After that, although the opening/closing execution mode ends at the timing of t7, the display corresponding to the number of times the round game is executed in the special display portion 429 is 5 is the first special figure display portion 425 or the second special figure display portion 426. It continues until a new game time in is started.

When the game is being played as described above, a display corresponding to the number of times the round game has been executed is displayed on the special display unit 429 in a situation where the first special map display unit 425 is displaying variable images. Similarly, in the situation where the display corresponding to the number of times the round game is executed is being displayed on the special display unit 429 as well, the variable display of the pattern is not displayed on the first special figure display unit 425. Further, when the game is being played as described above, a display corresponding to the number of times the round game has been executed is displayed on the special display unit 429 in a situation where the variable display of the pattern is being displayed on the second special figure display unit 426. Is not performed, and similarly, in a situation in which the display corresponding to the number of times the round game is executed is displayed on the special display unit 429, the variable display of the pattern is not displayed on the second special figure display unit 426. ..

Next, a situation in which the set value updating process (step SC216) is being executed will be described.

At the timing of t8, the set value updating process (step SC216) is started as shown in FIG. 226(a). In this case, at the timing of t8, as shown in FIG. 226(c), the first special figure display unit 425 switches from the extinguished state to the state in which the variable display of the pattern is performed. Further, at the timing of t8, as shown in FIG. 226(g), the special display unit 429 is switched from the extinguished state to a state in which a display corresponding to the number of times the round game is executed is 15 times.

After that, at the timing of t9, the set value updating process (step SC216) is finished as shown in FIG. 226(a). As a result, at the timing of t9, as shown in FIG. 226(c), the variable display of the pattern on the first special figure display portion 425 is finished. In this case, as shown in FIG. 226(d), the initial display is started on the first special figure display portion 425. The contents of the initial display are the same as the contents of the initial display of the special figure display portion 37a in the 56th embodiment. Further, at the timing of t9, as shown in FIG. 226(g), the display corresponding to the number of times the round game is executed on the special display portion 429 is 15 is ended. In this case, the special display unit 429 is turned off.

Next, a situation in which the setting confirmation process (step SC213) is being executed will be described.

At the timing of t10, the setting confirmation process (step SC213) is started as shown in FIG. 226(b). In this case, at the timing of t10, as shown in FIG. 226(e), the second special figure display unit 426 switches from the extinguished state to the state in which the variable display of the pattern is performed. Further, at the timing of t10, as shown in FIG. 226(g), the special display unit 429 is switched from the extinguished state to a state in which a display corresponding to the number of times the round game is executed is 6 times.

After that, at the timing of t11, the setting confirmation process (step SC213) ends as shown in FIG. 226(b). As a result, at the timing of t11, as shown in FIG. 226(e), the variable display of the pattern on the second special figure display portion 426 is finished. In this case, as shown in FIG. 226(f), the initial display is started on the second special figure display portion 426. The contents of the initial display are the same as the contents of the initial display of the special figure display portion 37a in the 56th embodiment. Also, at the timing of t11, the display corresponding to the number of times the round game is executed on the special display portion 429 is 6 as shown in FIG. 226(g) is ended. In this case, the special display unit 429 is turned off.

According to this embodiment described in detail above, the following excellent effects are exhibited.

In the situation where the set value updating process (step SC216) is being executed, the variable display of the pattern is performed on the first special figure display unit 425 and the display corresponding to the number of times the round game is executed is displayed on the special display unit 429. Be seen. When a game is being played, the special display unit 429 does not provide a display corresponding to the number of times the round game has been executed in a situation where the first special map display unit 425 is displaying variable images. .. Therefore, the manager of the game hall confirms that the variable display of the pattern is displayed on the first special view display unit 425 and the display corresponding to the number of times the round game is executed is displayed on the special display unit 429. By doing so, it becomes possible to grasp that the setting value update process (step SC216) is being executed.

In particular, the first special figure display portion 425 and the special display portion 429 are provided in a region visible from the front of the pachinko machine 10 through the window panel 52 without requiring the opening operation of the gaming machine body 12 and the front door frame 14. The first special figure display unit 425 and the special display unit 429 are informed that the setting value updating process (step SC216) is being executed, so that the setting value updating process (step SC216) is performed. It is possible to easily confirm whether or not the condition (1) is being executed.

Further, when the game is being played, the opening/closing execution mode is generated after the game times have been executed, so the special display unit 429 is displayed after the variable display of the pattern is performed on the first special figure display unit 425. A display corresponding to the number of round game executions is made. By performing the display of both of these execution periods before and after in the setting value updating process (step SC216) at the same time, the setting value updating process (step SC216) is being executed. It is possible to clearly notify that.

By the combination of the display contents of the first special figure display unit 425 and the special display unit 429, the notification indicating that the setting value update processing (step SC216) is being executed is performed. As a result, in order to illegally perform the notification indicating that the setting value update processing (step SC216) is being executed, the first special figure display unit 425 and the special display unit 429 are respectively notified. Therefore, it becomes necessary to cheat. Therefore, it becomes possible to make it difficult to perform the fraudulent act.

The first special view display unit 425 and the special display unit 429 are display units used when a game is being executed. By using such a display unit to notify that the setting value update process (step SC216) is being executed, the notification can be performed while suppressing the complication of the configuration. Become.

When the notification indicating that the setting value updating process (step SC216) is being executed is performed, the variable display of the pattern is performed on the first special figure display unit 425, and the round game is performed on the special display unit 429. The display corresponding to the number of times is performed. The variable display of the pattern on the first special view display unit 425 is the display content that occurs even when the game is being executed, and the display corresponding to the number of times the round game is executed on the special display unit 429 is the game being executed. This is the display content that also occurs when there is. As a result, it is possible to notify that the setting value update process (step SC216) is being executed by using the display content generated when the game is being executed.

The first special drawing display portion 425 and the special display portion 429 are provided as a special drawing unit 422 in a predetermined range. This makes it easy to confirm the display contents of the first special view display unit 425 and the special display unit 429.

In the situation where the game is being executed, when the display corresponding to the number of times the round game is executed is displayed on the special display section 429, the special electric prize winning device 416 is opened and closed. On the other hand, in the situation where the set value update processing (step SC216) is being executed, the special electric prize winning device 416 is in the closed state in the situation where the display corresponding to the execution count of the round game is displayed on the special display portion 429. Maintained at. As a result, it becomes possible to notify that the setting value update process (step SC216) is being executed.

In the situation where the setting confirmation process (step SC213) is being executed, the variable display of the pattern is performed on the second special figure display unit 426, and the display corresponding to the number of times the round game is executed is displayed on the special display unit 429. Be seen. When a game is being played, the special display unit 429 does not provide a display corresponding to the number of times the round game has been executed in a situation where the variable display of the pattern is being performed on the second special figure display unit 426. .. Therefore, the manager of the game hall confirms that the variable display of the pattern is displayed on the second special figure display unit 426 and the display corresponding to the number of times the round game is executed is displayed on the special display unit 429. By doing so, it becomes possible to grasp that the setting confirmation process (step SC213) is being executed.

In addition, whether the setting value update process (step SC216) is being executed or the setting confirmation process (step SC213) is being executed, the special display unit 429 corresponds to the number of round game executions. On the other hand, while the setting value updating process (step SC216) is being executed, the variable display of the pattern is displayed on the first special figure display unit 425, whereas the setting confirmation process (step SC213) is performed. (2) is executed, the variable display of the pattern is displayed on the second special figure display unit 426. As a result, the game hall manager can clearly distinguish which of the setting value update processing (step SC216) and the setting confirmation processing (step SC213) is being executed.

The fluctuation amount in each set value of the number of pieces of numerical value information of the hit random number counter C1 which is determined to be the big hit result in the hold determination processing for the hold information on the second special figure side is the hit or not for the hold information on the second special figure side. It is absorbed by the variation of the number of the numerical information of the random number counter C1 which is determined to be the deviation result in the determination processing. As a result, a big hit result is obtained in the hit/fail judgment processing for the hold information on the second special figure side while not affecting the probability of a small hit result in the hold information judgment processing for the second special figure side. It is possible to change the probability.

The number of numerical value information of the hit random number counter C1 which is determined to be a small hit result in the hit/miss determination processing for the hold information on the second special figure side is the same regardless of the set value. This makes it possible to make the probability that the small hit result is selected in the hit determination processing for the hold information on the second special figure side constant for all the set values. Even if the probability that the small hit result is selected in the hold determination process for the holding information on the second special figure side is constant in this way, Since the variation of each setting value of the probability that the jackpot result is selected is absorbed by the variation of the probability that the outlier result is selected, the jackpot result is selected in the hit/miss judgment process for the pending information on the second special map side. It is possible to set the probability of being performed according to the set value.

The number of pieces of numerical value information of the random number counter C1 that is determined to be a deviation result in the hit/miss determination processing for the pending information on the second special figure side is the largest regardless of each set value. Thereby, the deviation result is selected in the hit/miss judgment processing for the hold information on the second special figure side by the variation in each setting value of the probability that the jackpot result is selected in the hit/miss judgment processing for the hold information on the second special figure side. Even if it is configured to absorb the change in the probability, the probability that a deviation result will occur in the hold information on the second special map side will not cause a large change between the setting values in multiple stages. It becomes possible to do.

Instead of the configuration of the above-described embodiment, in the situation where the set value updating process (step SC216) is being executed, the variable display of the pattern is performed on the first special figure display unit 425 and the second special figure display unit is displayed. The variable display of the pattern may be performed at 426. When a game is being played, one of the first special figure display unit 425 and the second special figure display unit 426 is performing variable display of the pattern, and when the other is displaying variable display of the pattern. It is a structure that cannot be forgotten. In this case, in the situation where the set value updating process (step SC216) is executed as described above, the variable display of the patterns is performed on each of the first special figure display unit 425 and the second special figure display unit 426. This makes it possible to notify the manager of the game hall that the setting value updating process (step SC216) is being executed. In the case of notifying that the setting confirmation process (step SC213) is being executed in the configuration, a variable display of patterns is displayed on each of the first special figure display unit 425 and the second special figure display unit 426. In addition, a variable display of the pattern may be performed on the public figure display unit 423a. In addition to the variable display of the pattern on each of the first special figure display unit 425 and the second special figure display unit 426, the special display unit 429 may be displayed. Alternatively, the predetermined display may be performed.

Further, the display content displayed on the special display portion 429 in the situation where the set value update processing (step SC216) is executed is not limited to the configuration that is the display content corresponding to the number of times of execution of the round game, Although the display content does not correspond to the number of times the round game is executed, at least one display segment 429a in the special display unit 429 may be in a light emitting state to perform a predetermined display. When a game is being played, the first special map display unit 425 is displaying a variable pattern, and when the special display unit 429 is in a non-display state in which all the display segments 429a are turned off. Therefore, the setting value update process (step SC216) is executed because the special display unit 429 is not in the non-display state in the situation where the variable display of the pattern is being performed on the first special figure display unit 425. It becomes possible to inform that the situation is present. Also, in the situation where the setting confirmation process (step SC213) is being executed, the variable display of the pattern is displayed on the second special figure display unit 426 and the display corresponding to the number of times the round game is executed is displayed on the special display unit 429. However, the predetermined display may be performed.

In addition to or instead of the configuration of the above-described embodiment, a dedicated display unit for notifying that the setting value update process (step SC216) is being executed is provided in the gaming machine main body 12 and the front door frame. The structure may be provided in a region that can be viewed through the window panel 52 from the front of the pachinko machine 10 without requiring the opening operation of 14.

In addition to or instead of the configuration of the above-described embodiment, a dedicated display unit for notifying that the setting confirmation process (step SC213) is being executed is provided with the gaming machine main body 12 and the front door frame. The structure may be provided in a region that can be viewed through the window panel 52 from the front of the pachinko machine 10 without requiring the opening operation of 14.

Further, in addition to or instead of the configuration of the above-described embodiment, a dedicated display unit for notifying that the setting value updating process (step SC216) is being executed and the setting confirmation process (step SC213) are provided. Each of the dedicated display units for notifying that the situation is being executed becomes visible through the window panel 52 from the front of the pachinko machine 10 without requiring the opening operation of the gaming machine body 12 and the front door frame 14. The structure may be provided in the area.

Further, in addition to or in place of the configuration of the above-described embodiment, a dedicated value for notifying that the setting value update process (step SC216) or the setting confirmation process (step SC213) is being executed The display unit may be provided in a region visible from the front of the pachinko machine 10 through the window panel 52 without requiring the opening operation of the gaming machine body 12 and the front door frame 14. In this case, the notification is performed on the same dedicated display unit regardless of whether the setting value update process (step SC216) is being executed or the setting confirmation process (step SC213) is being executed. .. Further, in the configuration, the contents displayed on the same dedicated display section are different depending on whether the setting value updating process (step SC216) is being executed or the setting confirmation process (step SC213) is being executed. It may be configured to have.

Further, instead of the configuration of the above-described embodiment, the same notification is issued regardless of whether the setting value updating process (step SC216) is being executed or the setting confirmation process (step SC213) is being executed. It may be configured to be executed. Further, it may be configured such that one of the situation in which the setting value updating process (step SC216) is executed and the situation in which the setting confirmation process (step SC213) is executed is notified, but the other is not notified.

Further, in addition to or instead of the configuration of the above-described embodiment, even if the setting value updating process (step SC216) is executed as in the 55th embodiment, after the process at the start of supplying the operating power is executed, In the configuration in which the display at the last power failure is resumed on the 1 special figure display unit 425, the display data corresponding to the display at the previous power failure when the set value update process (step SC216) is started. Is saved from the first display data buffer 271 to the area in the main RAM 65 where the second RAM clearing process is not performed “0” clear and initialization, and is saved when the set value updating process (step SC216) is completed. The display data may be returned to the first display data buffer 271. As a result, in the situation where the set value update process (step SC216) is being executed, while the corresponding display is displayed on the first special figure display unit 425, after the set value update process (step SC216) is completed. It is possible to restart the display at the last power failure.

Further, in addition to or instead of the configuration of the above-described embodiment, a configuration may be provided in which a display unit corresponding to distribution execution is provided to display that the distribution execution mode is in the distribution execution mode. Good. The display unit corresponding to the distribution execution is switched from the non-display state (that is, the all extinguished state) to the predetermined display state when the distribution execution mode is started, and the predetermined display is displayed when the distribution execution mode ends. The state is switched to the non-display state. In the configuration, when the set value updating process (step SC216) is executed, the display unit corresponding to the distribution execution is brought into a predetermined display state and the special display unit 429 is brought into a predetermined display state. It is possible to notify that the value update process (step SC216) is being executed. Further, the configuration related to such notification may be applied to the situation where the setting confirmation process (step SC213) is being executed.

Further, in addition to or instead of the configuration of the above-described embodiment, the small hit result may be selected even when the holding information on the first special view side is the target of the hit determination processing. Even in this case, when the hit/non-judgment processing is executed for the pending information on the first special figure side, the variation in each set value of the number of numerical information of the hit random number counter C1 which is determined to be the jackpot result. However, it may be configured to be absorbed by a variation in the number of numerical information of the random number counter C1 which is determined to be a deviation result when the hit/miss determination processing is performed on the pending information on the first special view side. .. In this case, the probability that the small hit result is selected when the hit/miss determination process is executed for the hold information on the first special map side may be the same in each set value. Further, in place of the above configuration, when the hit/miss determination process is executed for the pending information on the first special figure side, the fluctuation in each set value of the number of numerical information of the hit random number counter C1 which is determined to be a jackpot result. As a configuration in which the minute is absorbed by the variation of the number of numerical information of the hit random number counter C1 which is determined to be a small hit result when the hit/miss determination processing is executed for the pending information on the first special map side Good.

Further, instead of the configuration of the above-described embodiment, each of the numbers of numerical information of the hit random number counter C1 which is determined to be a jackpot result when the hit/miss determination processing is executed for the pending information on the second special figure side. The fluctuation in the set value is absorbed by the fluctuation in the number of numerical information of the hit random number counter C1 which is determined to be the small hit result when the hit determination processing is executed for the hold information on the second special map side. It may be configured to be.

Further, in addition to or instead of the configuration of the above-described embodiment, as a configuration in which there is a high-probability mode and a low-probability mode in which the probability of being determined as a jackpot result in the hit determination processing is relatively high or low. Good. Further, in the configuration, even if the hit/disapproval determination process is executed for the hold information on the first special figure side, the small hit result can be selected, and the hold information on the first special figure side is hit/failed. Whether the small hit result is selected by executing the determination process or the small hit result is selected by executing the hit determination process for the holding information on the second special map side It may be configured to shift to the open/close execution mode instead of the mode. In the opening/closing execution mode, the special electric winning device 416 is configured to execute short opening for about 1 second a small number of times for about 2 times. As a type of jackpot result in the above-described configuration, in the opening/closing execution mode, the special electric prize winning device 416 is opened in the same manner as in the case of the small hit result, and becomes a high probability mode after the opening/closing execution mode ends. However, when the support mode before the start of the open/close execution mode is the low-frequency support mode, there may be a latent probability variation jackpot result in which the low-frequency support mode is maintained. In this case, in the case of the low probability mode and the low frequency support mode, when the special electric prize winning device 416 performs a short opening of about 1 second a small number of times about 2 times triggered by the holding information on the first special map side It is possible to let the player predict whether it is triggered by the small hit result or the latent probability variation big hit result. Further, in the configuration, the probability that the small hit result is selected when at least the hold information on the first special map side is executed is the same or not, regardless of whether the win/win lottery mode and the set value are set. By setting the configurations to be substantially the same, it is possible to prevent the player from grasping not only the set value but also the win/loss lottery mode from the occurrence frequency of the small hit result.

Further, in addition to or instead of the configuration of the above-described embodiment, when the opening/closing execution mode occurs due to a V prize in any of the distribution execution modes resulting in a small hit, the distribution already completed The execution mode may be one round, and a display corresponding to the number of times the round game is executed may be displayed on the special display unit 429. In this case, in the opening/closing execution mode triggered by the first small hit result, a display corresponding to six round games is displayed on the special display portion 429, and in the opening/closing execution mode triggered by the second small hit result, nine times. The display corresponding to the round game is displayed on the special display unit 429, and in the opening/closing execution mode triggered by the third small hit result, the display corresponding to the 15 round game is displayed on the special display unit 429.

Further, in addition to or instead of the configuration of the above-described embodiment, there is only one kind of small hit result, and when a V winning occurs in the distribution execution mode, the number of round games that occur in the subsequent opening/closing execution mode is The configuration may be determined by lottery. In this case, the player pays attention to the timing when the V winning occurs.

Further, in addition to or instead of the configuration of the above embodiment, the distribution probability of the type of the jackpot result may be changed according to the set value. In this case, the probability that the jackpot result is selected in the hit determination process may be changed according to the set value, and the probability that the jackpot result is selected in the hit determination process does not change according to the set value. The configuration may be constant.

<65th Embodiment>
In this embodiment, the processing configuration of the second timer interrupt processing is different from that in the 64th embodiment. Hereinafter, a configuration different from that of the 64th embodiment will be described. Note that the description of the same configuration as the 64th embodiment is basically omitted.

FIG. 227 is a flowchart showing the second timer interrupt processing in this embodiment. The processing of steps SE601 to SE615 in the second timer interrupt processing is executed using the program for specific control and the data for specific control in the main CPU 63.

First, similarly to step SE301 of the second timer interrupt processing (FIG. 224) in the 64th embodiment, interrupt prohibition is set (step SE601). Then, it is determined whether or not "1" is set in the setting update display flag in the work area 221 for specific control (step SE602). If the setting update display flag is set to "1" (step SE602: YES), the setting process for the fifth display data buffer 275 during the setting update is executed (step SE603). The processing content of the setting processing is the same as step SE303 of the second timer interrupt processing (FIG. 224) in the 64th embodiment.

After that, the setting process of the all-lit display during the setting update is executed (step SE604). In the setting processing, all the display segments of the public figure display unit 423a, all the light emitting units of the public figure reservation display unit 423b, all the display segments 425a of the first special image display unit 425, the second special image display unit All the display segments 426a of 426, all the light emitting parts of the first special figure reservation display part 427, all the light emitting parts of the second special figure reservation display part 428, and all the display segments 429a of the special display part 429. The light is turned on. That is, all of the display units which are display-controlled by the main CPU 63 and which are visible through the window panel 52 without requiring the opening operation of the gaming machine main body 12 and the front door frame 14 are in a light emitting state. This all-lit state is ended when the set value updating process (step SC216) is ended. The above-mentioned full lighting state does not occur in other situations including the situation in which the game is being played. Therefore, the manager of the game hall can confirm whether or not the set value updating process (step SC216) is being performed by confirming whether or not the above-described full lighting state is performed. ..

When a negative determination is made in step SE602, it is determined whether or not "1" is set in the setting confirmation display flag (step SE605). When the setting confirmation display flag is set to "1" (step SE605: YES), the setting process for the fifth display data buffer 275 during the setting confirmation is executed (step SE606). The processing content of the setting processing is the same as step SE307 of the second timer interrupt processing (FIG. 224) in the 64th embodiment.

After that, the setting process of the all-lighting display during the setting confirmation is executed (step SE607). In the setting process, all display segments 425a of the first special figure display unit 425, all display segments 426a of the second special figure display unit 426, all light emitting units of the first special figure reservation display unit 427, 2 All the light emitting parts of the special figure reservation display part 428 and all the display segments 429a of the special display part 429 are set to the light emitting state. That is, among the display units which are display-controlled by the main CPU 63 and which are visible through the window panel 52 without requiring the opening operation of the gaming machine main body 12 and the front door frame 14, the general-purpose display unit 423a and the general-purpose display unit 423a. All of the display units other than the figure hold display unit 423b are in the light emitting state. This fully lit state is terminated when the setting confirmation process (step SC213) is terminated. The above-mentioned full lighting state does not occur in other situations including the situation in which the game is being played. Therefore, the manager of the game hall can confirm whether or not the setting confirmation process (step SC213) is executed by confirming whether or not the above-mentioned full lighting state is performed. ..

When a negative determination is made in step SE605, the processes of steps SE608 to SE615 are executed. When the process of step SE604 or step SE607 is executed, the process of steps SE609 to SE615 is executed. The processing contents of these steps SE608 to SE615 are similar to those of steps SE310 to SE317 of the second timer interrupt processing (FIG. 224) in the 64th embodiment.

According to the above configuration, while the set value updating process (step SC216) is being executed, it is necessary to open the gaming machine main body 12 and the front door frame 14 in the display unit that is display-controlled by the main CPU 63. Instead, all of the display portions that can be viewed through the window panel 52 are in a light emitting state. Such a full lighting state does not occur in other situations including the situation where the game is being played. Therefore, the manager of the game hall can confirm whether or not the set value updating process (step SC216) is being performed by confirming whether or not the above-described full lighting state is performed. .. In addition, all the display units which are display-controlled by the main CPU 63 and which are visible through the window panel 52 without requiring the opening operation of the gaming machine main body 12 and the front door frame 14 are in a light emitting state. It becomes easier to specify whether or not the setting value updating process (step SC216) is being executed.

While the setting confirmation process (step SC213) is being executed, the window panel 52 is a display unit that is display-controlled by the main CPU 63 and does not require opening of the gaming machine main body 12 and the front door frame 14. Of the display units that can be visually recognized through, all of the display units other than the universal figure display unit 423a and the universal figure hold display unit 423b are in the light emitting state. Such a full lighting state does not occur in other situations including the situation where the game is being played. Therefore, the manager of the game hall can confirm whether or not the setting confirmation process (step SC213) is executed by confirming whether or not the above-mentioned full lighting state is performed. ..

The display unit in which all the display segments are in the light emitting state in the situation where the set value updating process (step SC216) is executed does not require the opening operation of the gaming machine main body 12 and the front door frame 14, and the window panel 52 The present invention is not limited to the configuration of all the display units that can be viewed through, and may be a configuration of a part of the display units. For example, in a situation where the set value updating process (step SC216) is being executed, all the display segments 425a and 429a of the first special figure display unit 425 and the special display unit 429 may be in a light emitting state. All of the display segments 425a and 426a of the first special figure display portion 425 and the second special figure display portion 426 may be in a light emitting state, and the general figure display portion 423a and the special display portion 429 may be respectively provided. All of the display segments may be in a light emitting state, or all of the display segments of the normal figure display section 423a, the second special figure display section 426 and the special display section 429 may be in a light emitting state. Good. The configuration may be applied as a configuration for notifying that the setting confirmation process (step SC213) is being executed.

<66th Embodiment>
In this embodiment, the processing configurations of the second timer interrupt processing and the set value updating processing are different from those in the 64th embodiment. Hereinafter, a configuration different from that of the 64th embodiment will be described. Note that the description of the same configuration as the 64th embodiment is basically omitted.

FIG. 228 is a flowchart showing the second timer interrupt processing in this embodiment. The processing of steps SE701 to SE715 in the second timer interrupt processing is executed using the specific control program and the specific control data in the main CPU 63.

First, in the same manner as in step SE301 of the second timer interrupt processing (FIG. 224) in the above 64th embodiment, interrupt prohibition is set (step SE701). Then, it is determined whether or not "1" is set in the setting update display flag in the work area 221 for specific control (step SE702).

When the setting update display flag is set to "1" (step SE702: YES), the setting process for the fifth display data buffer 275 during the setting update is executed (step SE703). The processing content of the setting processing is the same as step SE303 of the second timer interrupt processing (FIG. 224) in the 64th embodiment. After that, the setting process for the first display data buffer 271 during the setting update is executed (step SE704). The processing content of the setting processing is the same as step SE304 of the second timer interrupt processing (FIG. 224) in the 64th embodiment. As a result, in the situation where the set value updating process (step SC216) is being executed, the variable display of the pattern is performed on the first special figure display unit 425. On the other hand, in this embodiment, the process of step SE305 of the second timer interrupt process (FIG. 224) in the 64th embodiment is not executed. Therefore, in the present embodiment, in the situation where the set value updating process (step SC216) is being executed, the predetermined display is not displayed on the special display portion 429 and the extinguished state is maintained.

When a negative determination is made in step SE702, it is determined whether or not "1" is set in the setting confirmation display flag (step SE705). When the setting confirmation display flag is set to "1" (step SE705: YES), the setting process for the fifth display data buffer 275 during the setting confirmation is executed (step SE706). The processing content of the setting processing is the same as step SE307 of the second timer interrupt processing (FIG. 224) in the 64th embodiment. After that, the setting process for the sixth display data buffer 471 during the setting confirmation is executed (step SE707). The processing content of the setting processing is the same as step SE308 of the second timer interrupt processing (FIG. 224) in the 64th embodiment. As a result, in the situation where the setting confirmation process (step SC213) is being executed, the variable display of the pattern is performed on the second special figure display unit 426. On the other hand, in this embodiment, the process of step SE309 of the second timer interrupt process (FIG. 224) in the 64th embodiment is not executed. Therefore, in the present embodiment, in the situation where the setting confirmation process (step SC213) is being executed, a predetermined display is not displayed on the special display portion 429 and the extinguished state is maintained.

When a negative determination is made in step SE705, the processes of steps SE708 to SE715 are executed. When the processing of step SE704 or step SE707 is executed, the processing of steps SE709 to SE715 is executed. The processing contents of these steps SE708 to SE715 are similar to those of steps SE310 to SE317 of the second timer interrupt processing (FIG. 224) in the 64th embodiment.

FIG. 229 is a flowchart showing the setting value update processing in this embodiment. Note that the processing of step SE801 to step SE816 in the setting value update processing is executed using the specific control program and specific control data in the main CPU 63.

First, interrupt permission is set (step SE801). As a result, the first timer interrupt process (FIG. 133) is interrupted and activated in the first interrupt cycle, and the second timer interrupt process (FIG. 228) is interrupted and activated in the second interrupt period.

After that, the special electric winning device 416 is opened (step SE802). In the opening process, output of a drive signal to the special electric drive unit 416c provided in the special electric winning device 416 is started. As a result, the special electric winning device 416 is opened. After that, the processing for updating the set value is executed in steps SE803 to SE812, the interrupt prohibition is set in step SE813, the second RAM clear processing is executed in step SE814, and the update is executed in step SE815. Send the return command of. The processing contents of these steps SE803 to SE815 are the same as those of steps SB302 to SB314 of the setting value update processing (FIG. 167) in the forty-ninth embodiment.

After that, the special electric prize winning device 416 is closed (step SE816). In the closing process, the output of the drive signal to the special electric drive unit 416c provided in the special electric winning device 416 is stopped. As a result, the special electric winning device 416 is closed.

With the above configuration, in the present embodiment, in the situation where the setting value updating process (step SC216) is being executed, the variable display of the pattern is executed on the first special figure display unit 425, and the special electric prize winning device 416 is It will be open. When a game is being played, the special electric prize winning device 416 is opened in a situation where the game times corresponding to the jackpot result are executed and the pattern corresponding to the jackpot result is stopped and displayed on the first special map display portion 425. It becomes a state. That is, when a game is being played, the special electric prize winning device 416 will not be opened in a situation where the variable display of the pattern is being executed on the first special figure display unit 425. On the other hand, in the situation where the set value updating process (step SC216) is being executed, the variable display of the pattern is executed on the first special figure display unit 425 and the special electric prize winning device 416 is opened. This makes it possible to notify that the setting value update process (step SC216) is being executed by using the first special figure display unit 425 and the special electric winning device 416.

In addition, in the situation where the set value updating process (step SC216) is being executed, the special display portion 429 is maintained in the non-display state even though the special power winning device 416 is in the open state. When a game is being played, when the special electric prize winning device 416 is in an open state, a display corresponding to the number of times the round game is executed is displayed on the special display section 429. Therefore, the manager of the game hall sets by confirming that the display corresponding to the number of round games executed is not displayed on the special display section 429 although the special electric winning device 416 is in the open state. It is possible to understand that the value update process (step SC216) is being executed.

In particular, in the situation where the set value updating process (step SC216) is being executed, all the display segments 429a of the special display portion 429 are kept in the off state, even though the special power winning device 416 is in the open state. By doing so, the special display portion 429 is brought into a non-display state. Thereby, the manager of the game hall confirms whether or not any display is displayed on the special display section 429 in the situation where the special electric prize winning device 416 is in the open state, and the set value updating process (step SC216). It is possible to clearly understand that the situation is being executed.

Here, even in the situation where the setting confirmation process (step SC213) is being executed, the special power winning device 416 is in the open state as in the situation where the setting value updating process (step SC216) is being executed. Further, in the situation where the setting confirmation process (step SC213) is being executed, the variable display of the pattern is displayed on the second special figure display portion 426. When the game is being played, the game times corresponding to the big hit result or the small hit result are executed, and the symbols corresponding to the big hit result or the small hit result are stopped and displayed on the second special figure display portion 426. In a situation, the special electric prize winning device 416 is opened. That is, when a game is being played, the special electric prize winning device 416 is not opened in a situation where the variable display of the pattern is being executed on the second special figure display unit 426. On the other hand, in the situation where the setting confirmation process (step SC213) is being executed, the variable display of the pattern is executed on the second special figure display portion 426 and the special electric prize winning device 416 is opened. Thereby, it is possible to notify that the setting confirmation process (step SC213) is being executed by using the second special figure display unit 426 and the special electric winning device 416.

Note that instead of the configuration of the above-described embodiment, it is notified that the setting value update process (step SC216) is being executed or the setting confirmation process (step SC213) is being executed. In order to do so, it is also possible to have a configuration in which the variable display of the pattern is displayed on the universal figure display unit 423a and the guiding unit 432 of the second operating unit 413 is in the guiding state. When a game is being played, the situation in which the variable display of the picture is being displayed on the universal figure display unit 423a and the situation in which the guidance unit 432 of the second operation unit 413 is in the guidance state do not occur at the same time. Therefore, by generating these situations at the same time, it is possible to confirm that the situation is one of the situation in which the setting value update processing (step SC216) is being executed and the situation in which the setting confirmation processing (step SC213) is being executed. It becomes possible to inform.

Further, instead of the configuration of the above-described embodiment, it is notified that the setting value update process (step SC216) is being executed or the setting confirmation process (step SC213) is being executed. In order to do so, both the distribution winning apparatus 415 and the special electric winning apparatus 416 may be opened. When a game is being played, there is no situation in which both the distribution prize winning device 415 and the special electric prize winning device 416 are in the open state, so both the distribution prize winning device 415 and the special electric prize device 416 are in the open state. By doing so, it is possible to notify that the setting value update process (step SC216) is being executed or the setting confirmation process (step SC213) is being executed. ..

Further, instead of the configuration of the above-described embodiment, a plurality of special electric prize winning devices 416 that are in an open state in the opening/closing execution mode are provided, and when a game is being played, the plurality of special electric prize winning devices 416 are simultaneously opened. In the configuration that does not occur, to notify that one of the situation where the setting value update processing (step SC216) is being executed and the situation for which the setting confirmation processing (step SC213) is being executed is Further, the plurality of special electric prize winning devices 416 may be simultaneously opened.

Further, instead of the configuration of the above-described embodiment, it is notified that the setting value update process (step SC216) is being executed or the setting confirmation process (step SC213) is being executed. In order to do so, the special electric prize winning device 416 may be in an open state, but the degree of the open may be smaller than that in the open state when a game is being played.

Further, in addition to or instead of the configuration of the above-described embodiment, a distribution execution corresponding display unit that performs a predetermined display in the distribution execution mode is provided, and the set value update processing (step SC216) is executed. The special display section 429 is displayed in the situation where the special electric prize winning device 416 is in the open state in order to notify that the situation is one of the current situation and the situation where the setting confirmation process (step SC213) is being performed. It is also possible to have a configuration in which both the display unit and the display unit that supports distribution execution are turned off.

In addition to or instead of the configuration of the above-described embodiment, it is one of a situation in which the setting value update processing (step SC216) is being executed and a situation in which the setting confirmation processing (step SC213) is being executed. In order to notify that, the special electric prize winning device 416 may be opened and a display different from the display corresponding to the number of times the round game is executed may be displayed on the special display portion 429.

<67th Embodiment>
In this embodiment, the processing configuration of the second timer interrupt processing is different from that in the 64th embodiment. Hereinafter, a configuration different from that of the 64th embodiment will be described. Note that the description of the same configuration as the 64th embodiment is basically omitted.

FIG. 230 is a flowchart showing the second timer interrupt process in this embodiment. The processing of steps SE901 to SE915 in the second timer interrupt processing is executed by using the program for specific control and the data for specific control in the main CPU 63.

First, in the same manner as in step SE301 of the second timer interrupt processing (FIG. 224) in the above 64th embodiment, interrupt prohibition is set (step SE901). Then, it is determined whether or not "1" is set in the setting update display flag in the work area 221 for specific control (step SE902).

When the setting update display flag is set to "1" (step SE902: YES), the setting process for the fifth display data buffer 275 during the setting update is executed (step SE903). The processing content of the setting processing is the same as step SE303 of the second timer interrupt processing (FIG. 224) in the 64th embodiment.

After that, the display data during the setting update is set in the first display data buffer 271 (step SE904). The display data during the setting update is continuously stored in the first display data buffer 271 until the second RAM clear process is executed in the set value update process (step SC216), and the second RAM clear process is executed. "0" is cleared.

The setting update display data is display data for causing the first special figure display unit 425 to perform setting update display. The setting update display is not included in the display contents displayed when the variable display of the pattern is performed on the first special figure display portion 425 in the game time, and the result and the type of the winning/deciding determination process in the game time are further included. It is also not included in the display content of the pattern stopped and displayed on the first special figure display unit 425 to notify the result of the determination process. In other words, the setting update display has a display content that is not displayed on the first special view display unit 425 in the situation where the game is being executed. Further, the setting update display has a display content that is not displayed on the first special figure display unit 425 in a situation where the setting value update processing (step SC216) is not executed. Accordingly, by confirming whether or not the setting update display is being performed on the first special figure display unit 425, it is possible to grasp whether or not the setting value update processing (step SC216) is being executed. It becomes possible to do.

Specifically, the display content of the setting updating display is such that all the display segments 425a of the first special figure display portion 425 are in the light emitting state. In other words, in the setting updating display, the display segment 425a that can be in the light emitting state in the situation where the game is being played is in the light emitting state, but the combination of the display segments 425a that is in the light emitting state is in the situation where the game is being played. The combination is not selected in. Note that the display content of the setting update display is not limited to the above, and may be the display content in which only the display segment 425a that does not become the light emitting state in the situation where the game is played becomes the light emitting state.

On the other hand, in this embodiment, the process of step SE305 of the second timer interrupt process (FIG. 224) in the 64th embodiment is not executed. Therefore, in the present embodiment, in the situation where the set value updating process (step SC216) is being executed, the predetermined display is not displayed on the special display portion 429 and the extinguished state is maintained.

When a negative determination is made in step SE902, it is determined whether or not "1" is set in the setting confirmation display flag (step SE905). When the setting confirmation display flag is set to "1" (step SE905: YES), the setting process for the fifth display data buffer 275 during the setting confirmation is executed (step SE906). The processing content of the setting processing is the same as step SE307 of the second timer interrupt processing (FIG. 224) in the 64th embodiment.

Then, the setting confirmation display data is set in the sixth display data buffer 471 (step SE907). The display data during the setting confirmation is continuously stored in the sixth display data buffer 471 until the setting confirmation processing (step SC213) is completed, and is cleared to "0" when the setting confirmation processing (step SC213) is completed. It

The setting confirmation display data is display data for causing the second special figure display unit 426 to perform the setting confirmation display. The setting confirmation display is not included in the display contents displayed when the variable display of the pattern is performed on the second special figure display unit 426 in the game time, and the result and the type of the winning/failing determination process in the game time. It is also not included in the display content of the pattern stopped and displayed on the second special figure display unit 426 to notify the result of the determination process. That is, the setting confirmation display has a display content that is not displayed on the second special figure display portion 426 in the situation where the game is being executed. Further, the setting confirmation display has a display content that is not displayed on the second special figure display unit 426 in the situation where the setting confirmation process (step SC213) is not executed. Thus, by confirming whether or not the setting confirmation display is being displayed on the second special figure display unit 426, it is possible to grasp whether or not the setting confirmation process (step SC213) is being executed. It becomes possible to do.

Specifically, the display content of the setting confirmation display is such that all the display segments 426a of the second special figure display portion 426 are in a light emitting state. That is, in the setting confirmation display, the display segment 426a that can be in the light emitting state in the situation in which the game is being played is in the light emitting state, but the combination of the display segments 426a in the light emitting state is in the situation in which the game is being played The combination is not selected in. The display content of the setting confirmation display is not limited to the above-mentioned display content, and may be the display content in which only the display segment 426a that is not in the light emitting state in the situation where the game is played is in the light emitting state.

On the other hand, in this embodiment, the process of step SE309 of the second timer interrupt process (FIG. 224) in the 64th embodiment is not executed. Therefore, in the present embodiment, in the situation where the setting confirmation process (step SC213) is being executed, a predetermined display is not displayed on the special display portion 429 and the extinguished state is maintained.

When a negative determination is made in step SE905, the processes of steps SE908 to SE915 are executed. When the processing of step SE904 or step SE907 is executed, the processing of steps SE909 to SE915 is executed. The processing contents of these steps SE908 to SE915 are the same as those of steps SE310 to SE317 of the second timer interrupt processing (FIG. 224) in the 64th embodiment.

According to the above configuration, in the situation where the set value update process (step SC216) is being executed, the special display content indicating that the set value update process (step SC216) is being executed on the first special figure display unit 425. The setting update display is displayed. As a result, it becomes possible to notify whether or not the setting value update processing (step SC216) is being executed using the first special figure display unit 425.

Also, in the situation where the setting confirmation process (step SC213) is being executed, the second special figure display portion 426 is a display content dedicated for indicating that the setting confirmation process (step SC213) is being executed. The confirmation is displayed. As a result, it becomes possible to inform whether or not the setting confirmation process (step SC213) is being executed using the second special figure display unit 426.

In addition to or instead of the configuration of the above-described embodiment, it is one of the situation in which the setting value update processing (step SC216) is executed and the situation in which the setting confirmation processing (step SC213) is executed. In order to inform that, a special display that is not displayed when a game is being played on the special display unit 429 may be provided.

In addition to or instead of the configuration of the above-described embodiment, it is one of a situation in which the setting value update processing (step SC216) is being executed and a situation in which the setting confirmation processing (step SC213) is being executed. In order to notify that, a dedicated display that is not displayed when a game is being played on both the first special view display unit 425 and the special display unit 429 may be provided.

Further, in addition to or instead of the configuration of the above-described embodiment, it is one of a situation in which the setting value update processing (step SC216) is being executed and a situation in which the setting confirmation processing (step SC213) is being executed. In order to inform that, a dedicated display which is not displayed when a game is being played may be performed on both the second special figure display unit 426 and the special display unit 429.

In addition to or instead of the configuration of the above-described embodiment, it is one of a situation in which the setting value update processing (step SC216) is being executed and a situation in which the setting confirmation processing (step SC213) is being executed. In order to notify that, a dedicated display which is not displayed when a game is being played may be performed on both the first special figure display unit 425 and the second special figure display unit 426.

In addition to or instead of the configuration of the above-described embodiment, it is one of a situation in which the setting value update processing (step SC216) is being executed and a situation in which the setting confirmation processing (step SC213) is being executed. In order to notify that, a dedicated display, which is not displayed when a game is being played, may be displayed on the universal figure display unit 423a.

<68th Embodiment>
In the present embodiment, the configuration for notifying that the setting value updating process (step SC216) is being executed and the setting confirmation process (step SC213) is being executed is the 64th structure. This is different from the embodiment. Hereinafter, a configuration different from that of the 64th embodiment will be described. Note that the description of the same configuration as the 64th embodiment is basically omitted.

FIG. 231(a) is an explanatory diagram for explaining the configuration of the special display unit 429 in this embodiment.

On the special display section 429, four light emitting sections 481 to 484 are provided side by side at equal intervals. The leftmost light emitting unit 481 of the four light emitting units 481 to 484 is a 15R display unit 481 for notifying that the round game is to be executed 15 times, and the display unit 482 on the right side thereof has 9 round games. It is the 9R display unit 482 for notifying that it will be executed, and the display unit 483 on the right side thereof is the 6R display unit 483 for notifying that the round game is executed 6 times, and the display unit 484 at the right end. Is a small hit display portion 484 for notifying that the distribution execution mode is set.

At the position adjacent to the 15R display unit 481 (specifically, the lower position), the number "15" is displayed as the 15R display unit 485 indicating that the 15R display unit 481 is capable of executing 15 round games. It is printed. At the position adjacent to the 9R display unit 482 (specifically, the lower position), the number "9" is displayed as the 9R display unit 486 indicating that the 9R display unit 482 corresponds to the execution of nine round games. It is printed. A number "6" is displayed as a 6R clarification unit 487 at a position (specifically, a lower position) adjacent to the 6R display unit 483, which indicates that the 6R display unit 483 is capable of executing six round games. It is printed. On the other hand, no explicit portion is provided at a position adjacent to the small hit display portion 484 to indicate that the small hit display portion 484 corresponds to the execution of the distribution execution mode.

When the result of the hit determination processing and the type determination processing is the 15R jackpot result and the opening/closing execution mode is started, the 15R display unit 481 changes from the extinguished state to the light emitting state. Then, the 15R display unit 481 is maintained in the light emitting state while the opening/closing execution mode is being executed, and when the opening/closing execution mode is finished, the 15R display unit 481 is turned off from the light emitting state. In addition, an opening/closing execution mode in which 14 round games are executed due to a V prize being generated in the distribution execution mode triggered by the result of the hit/miss determination processing and the type determination processing being the third small hit result. When the 15R display section 481 is started, the 15R display unit 481 is changed from the extinguished state to the light emitting state. Then, the 15R display unit 481 is maintained in the light emitting state while the opening/closing execution mode is being executed, and when the opening/closing execution mode is finished, the 15R display unit 481 is turned off from the light emitting state.

Opening/closing execution mode in which 8 rounds of games are executed due to occurrence of V prize in the distribution execution mode triggered by the result of the win/loss judgment processing and the classification judgment processing being the second small hit result In this case, the 9R display unit 482 changes from the extinguished state to the light emitting state. Then, the 9R display unit 482 is maintained in the light emitting state while the opening/closing execution mode is being executed, and the 9R display unit 482 is turned off from the light emitting state when the opening/closing execution mode is ended.

When the result of the hit/miss determination process and the type determination process is the 6R jackpot result and the opening/closing execution mode is started, the 6R display unit 483 changes from the extinguished state to the light emitting state. Then, the 6R display unit 483 is maintained in the light emitting state while the opening/closing execution mode is being executed, and when the opening/closing execution mode is finished, the 6R display unit 483 is turned off from the light emitting state. In addition, an opening/closing execution mode in which five round games are executed due to the occurrence of a V prize in the distribution execution mode triggered by the result of the hit/miss determination processing and the type determination processing being the first small hit result. When 6 is started, the 6R display unit 483 changes from the extinguished state to the light emitting state. Then, the 6R display unit 483 is maintained in the light emitting state while the opening/closing execution mode is being executed, and when the opening/closing execution mode is finished, the 6R display unit 483 is turned off from the light emitting state.

When the result of the hit determination processing and the type determination processing is any of the first small hit result, the second small hit result, and the third small hit result, and when the distribution execution mode is started, the small hit display portion 484 is turned off. The light is turned on. Then, the small hit display unit 484 is maintained in the light emitting state while the distribution execution mode is being executed, and when the distribution execution mode is finished, the small hit display unit 484 is turned off from the light emitting state.

With the above configuration, in a situation where a game is being played, a plurality of display sections 481 to 484 among the 15R display section 481, 9R display section 482, 6R display section 483 and small hit display section 484 are in a light emitting state at the same time. It never happens. On the other hand, in the present embodiment, in the situation where the setting value update processing (step SC216) is being executed and the setting confirmation processing (step SC213) is being executed, the 15R display portion 481, 9R display portion 482, Of the 6R display portion 483 and the small hitting display portion 484, a plurality of display portions 481 to 484 are simultaneously in a light emitting state.

FIG. 231(b) shows the display contents of the 15R display unit 481, 6R display unit 483, and small hitting display unit 484 in the situation where the setting value update process (step SC216) or the setting confirmation process (step SC213) is being executed. It is a time chart. FIG. 231(b1) shows the period during which the setting value updating process (step SC216) is executed, FIG. 231(b2) shows the period during which the setting confirmation process (step SC213) is executed, and FIG. 231(b3). ) Indicates a period during which the 15R display portion 481 is in a light emitting state, FIG. 231 (b4) indicates during a period when the 6R display portion 483 is in a light emitting state, and FIG. 231 (b5) indicates that the small hit display portion 484 is The period during which the light is emitted is shown.

At the timing of t1, the set value updating process (step SC216) is started as shown in FIG. 231(b1). In this case, at the timing of t1, the 15R display unit 481 switches from the extinguished state to the light emitting state as shown in FIG. 231(b3), and the small hitting display unit 484 emits light from the unlit state as shown in FIG. 231(b5). Switch to the state. Then, the light emission states of the 15R display portion 481 and the small hit display portion 484 are continued while the set value update processing (step SC216) is being executed.

After that, at the timing of t2, the set value updating process (step SC216) is ended as shown in FIG. 231(b1). As a result, at the timing of t2, the 15R display unit 481 is switched from the light emitting state to the extinguished state as shown in FIG. 231(b3), and the small hitting display unit 484 is extinguished from the light emitting state as shown in FIG. 231(b5). Switch to the state.

Further, at the timing of t3, the setting confirmation process (step SC213) is started as shown in FIG. 231(b2). In this case, at the timing of t3, the 15R display unit 481 is switched from the extinguished state to the light emitting state as shown in FIG. 231(b3), and the 6R display unit 483 is switched from the unlit state to the light emitting state as shown in FIG. 231(b4). Switch to. The light emission states of the 15R display unit 481 and the 6R display unit 483 are continued while the setting confirmation process (step SC213) is being executed.

After that, at the timing of t4, the setting confirmation process (step SC213) ends as shown in FIG. 231(b2). As a result, at the timing of t4, the 15R display unit 481 switches from the light emitting state to the extinguished state as shown in FIG. 231(b3), and the 6R display unit 483 from the light emitting state to the extinguished state as shown in FIG. 231(b4). Switch to.

According to the above configuration, both the 15R display portion 481 and the small hit display portion 484 are in the light emitting state in the situation where the set value update processing (step SC216) is being executed. The situation in which both the 15R display portion 481 and the small hit display portion 484 are in the light emitting state does not occur in a situation in which the set value update processing (step SC216) is not executed including the situation in which the game is being executed. This makes it possible to notify whether or not the setting value updating process (step SC216) is being executed using the 15R display unit 481 and the small hit display unit 484.

In the situation where the setting confirmation process (step SC213) is being executed, both the 15R display portion 481 and the 6R display portion 483 are in the light emitting state. The situation in which both the 15R display portion 481 and the 6R display portion 483 are in the light emitting state does not occur in the situation where the setting confirmation process (step SC213) is not executed, including the situation where the game is being executed. This makes it possible to notify whether or not the setting confirmation process (step SC213) is being executed using the 15R display unit 481 and the 6R display unit 483.

<69th Embodiment>
In this embodiment, the contents of the game executed are different from those of the 64th embodiment. Hereinafter, a configuration different from that of the 64th embodiment will be described. Note that the description of the same configuration as the 64th embodiment is basically omitted.

FIG. 232 is a front view of the game board 24 in the present embodiment.

Even in the present embodiment, the inner rail portion 401 and the outer rail portion 402 are attached to the game board 24 so as to partition a part of the outer edge of the game area PA. A guide rail as guide means is configured with the rail portion 402. The game board 24 is formed with a plurality of large and small openings penetrating in the front-rear direction. A general winning portion 411, a first operating portion 412, a second operating portion 413, a through winning portion 414, a special electricity winning device 416, a variable display unit 421, a special drawing unit 422, a general drawing unit 423, etc. are provided in each opening. Has been. The game area PA is divided by the variable display unit 421 into an upper area PA1, a left area PA2, a right area PA3, and a lower area PA4. The general winning portion 411, the first operating portion 412, the second operating portion 413, the through winning portion 414, the special electric prize winning device 416, the variable display unit 421, the special drawing unit 422, and the general drawing unit 423 are the 64th embodiment. And the arrangement position in the game area PA is also the same as in the 64th embodiment. However, in the present embodiment, the distribution winning apparatus 415 according to the 64th embodiment is not provided.

Even if a game ball enters the through winning portion 414, the game ball is not paid out. On the other hand, when a game ball enters any one of the general winning portion 411, the first operating portion 412, the second operating portion 413, and the special electric winning device 416, the number of game media usable by the player is increased. Therefore, a predetermined number of game balls are paid out. Regarding the number of prize balls, specifically, when the game balls enter the general prize unit 411, 10 game balls are paid out, and the game balls enter the first operation unit 412. When three game balls are paid out, the game ball is paid out to the second operating unit 413, one game ball is paid out, and the special prize winning device 416 is executed. When a game ball enters the game ball, payout of 15 game balls is executed.

In the area above the through winning portion 414 in the right area PA3, a first guide nail 491a that guides all the game balls flowing down the right area PA3 to the through winning portion 414 is provided. Since the first guide nail 491a is provided, all the game balls flowing down the right side area PA3 will pass through the through winning portion 414. However, since the game balls that have won the through winning part 414 continue to flow down in the right side area PA3 as they are, the second operating part 413 and the special electricity winning a prize provided on the downstream side of the through winning part 414 in the right side area PA3. A prize for device 416 may occur. It should be noted that all the game balls that have flowed into the right side area PA3 are not limited to the configuration in which all of the through winning portions 414 are won, and the game balls that flow into the right side area PA3 have a high probability of through winning such as 9/10. The prize may be awarded to the section 414.

A second guide nail 491b that guides all of the game balls flowing down the right side area PA3 to the second operation section 413 in an area below the through winning section 414 in the right side area PA3 and above the second operation section 413. Is provided. Since the second guiding nail 491b is provided, all the game balls flowing down the right side area PA3 will surely flow into the passage portion 439a formed by the cover member 439 of the second operating portion 413. Therefore, in the situation where the guiding unit 432 of the second operating portion 413 is in the guiding state, the game ball that flows into the right side area PA3 and is guided to the second operating portion 413 by the second guiding nail 491b is surely the second operating portion 413. Will enter the ball. On the other hand, in the situation where the guiding unit 432 of the second operating portion 413 is in the non-guided state, the game ball that has flowed into the right side area PA3 and is guided to the second operating portion 413 by the second guiding nail 491b is the second operating portion 413. The cover member 439 flows into the passage portion 439a but does not enter the second operating portion 413. This game ball will pass through the passage portion 439a and flow down on the downstream side of the second operating portion 413. For example, when the special electric prize winning device 416 is in an open state, this game ball will enter the special electric prize winning device 416 with a high probability. In addition, when the special electric prize winning device 416 is in an open state, this game ball may be configured to surely enter the special electric prize winning device 416.

In the above configuration, when the game balls enter the second operating unit 413, the number of payout game balls is one, so even if the game balls frequently enter the second operating unit 413, the number of payouts is substantially one. The game balls owned by the player do not increase. On the other hand, when the guiding unit 432 of the second operating portion 413 is in the non-guided state, even the game ball guided by the second guiding nail 491b does not enter the second operating portion 413. Therefore, even if the support mode is the high-frequency support mode and the guidance unit 432 is in the guidance state at a high frequency, as long as the opening/closing execution mode occurs and the game ball does not enter the special power winning device 416. , Even if the number of game balls owned by the player becomes difficult to decrease, it does not increase.

Next, an electrical configuration for the main CPU 63 to perform various lottery will be described with reference to FIG. 233.

The main CPU 63 uses various counter information at the time of a game to perform a winning lottery, setting of display of special symbol display portions 425 and 426, setting of symbol display of the symbol display device 424, setting of display of the general symbol display portion 423a, etc. Specifically, as shown in FIG. 233, the hit random number counter C1 used in the lottery for winning, the type counter C2 used in determining the jackpot type, and the symbol display device 424 are removed. The reach random number counter C3 used for the reach generation lottery when changing, the random number initial value counter CINI used for the initial value setting of the hit random number counter C1, the special figure display parts 425, 426 and the symbol display device 424 of the gaming machine. The fluctuation type counter CS for determining the display continuation period is used. Further, the universal electric accessory release counter C4 used in the lottery for determining whether or not the guidance unit 432 of the second operation unit 413 is in the guidance execution state is used. The counters C1 to C3, CINI, CS and C4 are provided in various counter areas 65b of the main RAM 65.

Each of the counters C1 to C3, CINI, CS, and C4 is a loop counter in which 1 is added to the previous value each time it is updated, and after reaching the maximum value, it returns to "0". Each counter is updated at short time intervals. The information corresponding to the winning random number counter C1, the type counter C2, and the reach random number counter C3 is a special figure holding area provided in the main side RAM 65 when the winning of the first operating unit 412 or the second operating unit 413 occurs. 451 is stored. The special figure reservation area 451 includes a first special figure reservation area 452, a second special figure reservation area 453, and a special figure execution area 492.

The first special figure reservation area 452 includes a first area 452a, a second area 452b, a third area 452c and a fourth area 452d, and a winning random number counter C1 according to the winning history of the first operating unit 412, Numerical information of each of the type counter C2 and the reach random number counter C3 is stored in any of the areas 452a to 452d as pending information on the special drawing side. In this case, in the first area 452a to the fourth area 452d, when the winning of the first operating portion 412 occurs a plurality of times in succession, the first area 452a→the second area 452b→the third area 452c→the fourth area. Numerical information is sequentially stored in the order of the four areas 452d. Since the four areas 452a to 452d are provided in this manner, the winning history of the game balls to the first actuating portion 412 can be reserved and stored up to a maximum of four. Note that the number that can be reserved and stored in the first special figure reservation area 452 is not limited to four and is arbitrary, and may be two, three, or five or more other numbers. , May be singular.

The second special figure reservation area 453 is provided with a first area 453a, a second area 453b, a third area 453c and a fourth area 453d, and a winning random number counter C1 according to the winning history to the second operating unit 413, Numerical information of each of the type counter C2 and the reach random number counter C3 is stored in any of the areas 453a to 453d as reserved information on the special drawing side. In this case, in the first area 453a to the fourth area 453d, when the winning of the second operating portion 413 occurs a plurality of times in succession, the first area 453a→the second area 453b→the third area 453c→the third area 453c. Numerical information is sequentially stored in the order of the four areas 453d. Since the four areas 453a to 453d are provided in this manner, the winning history of the game balls to the second operating unit 413 can be reserved and stored up to a maximum of four. In addition, the number that can be reserved and stored in the second special figure reservation area 453 is not limited to four, and may be any number, and may be two, three, or five or more other numbers. , May be singular.

The special figure execution area 492 includes a first special figure execution area 493 and a second special figure execution area 494. The execution area 493 for the first special figure is the side of the first special figure that is the target for performing the right/wrong determination processing or the type determination processing for the special figure when the variable display of the pattern is started on the first special figure display unit 425. Is an area in which the reservation information of is stored. The execution area 494 for the second special figure is the side of the second special figure that is the target for performing the right/wrong determination processing and the type determination processing for the special figure when the variable display of the pattern is started on the second special figure display unit 426. Is an area in which the reservation information of is stored. Specifically, when the variable display of the pattern on the first special figure display unit 425 is started, the holding information on the first special figure side stored in the first area 452a of the first special figure holding area 452 is the first. 1 Moved to execution area 493 for special drawing. On the other hand, when starting the variable display of the pattern on the second special figure display portion 426, the second special figure side hold information stored in the first area 453a of the second special figure holding area 453 is the second special figure. Is moved to the execution area 494 for.

The information corresponding to the universal electric accessory release counter C4 is stored in the universal figure holding area 455 provided in the main side RAM 65 when a prize is awarded to the through winning portion 414. The universal figure holding area 455 is provided with a first area 455a, a second area 455b, a third area 455c and a fourth area 455d, and in accordance with the winning history of the through winning part 414, the universal electric accessory release counter C4. The numerical value information is stored in any of the areas 455a to 455d as the reservation information on the universal figure side. In this case, in the first area 455a to the fourth area 455d, when the winning in the through winning part 414 occurs a plurality of times in succession, the first area 455a→the second area 455b→the third area 455c→the fourth area. Numerical information is stored in time series in the order of the area 455d. Since the four areas 455a to 455d are provided in this manner, the winning history of the game balls to the through winning portion 414 can be reserved and stored up to a maximum of four. Note that the number that can be reserved and stored in the universal figure reservation area 455 is not limited to four, and may be any number, and may be other plural numbers such as two, three, or five or more. May be

An execution area 456 for a general figure is provided in the general figure reservation area 455. The execution area 456 for the general figure is the side of the general figure that is the target of the induction state lottery for determining whether or not the induction unit 432 is in the induction state when the variable display is started on the general figure display unit 423a. Is an area in which the reservation information of is stored. Specifically, when the variable display of the universal figure display unit 423a is started, the universal figure hold information stored in the first area 455a of the universal figure holding area 455 is moved to the universal figure execution area 456. To be done.

Of the counters C1 to C3, CINI, CS, and C4, the configurations related to the reach random number counter C3, the random number initial value counter CINI, and the universal utility accessory release counter C4 are the same as those in the 64th embodiment. On the other hand, the configurations related to the random number counter C1, the type counter C2, and the variation type counter CS are different from those in the 64th embodiment. Hereinafter, the configurations related to the random number counter C1, the type counter C2, and the variation type counter CS will be described. In the present embodiment, the reach display does not occur in the symbol display device 424 in the game times corresponding to the small hit result, and the combination of the same symbols is not stopped and displayed after the variable display of the symbols.

First, the hit random number counter C1 will be described. The hit random number counter C1 is configured to be sequentially incremented by 1 in the range of 0 to 9999, and returned to "0" after reaching the maximum value. In particular, when the hit random number counter C1 makes one round, the value of the random number initial value counter CINI at that time is read as the initial value of the hit random number counter C1. The random number initial value counter CINI is a loop counter similar to the random number counter C1 (value=0 to 9999). The hit random number counter C1 is regularly updated, and is stored in the special figure reservation area 451 of the main side RAM 65 at the timing when the game ball wins the first operating unit 412 or the second operating unit 413. Then, the hit/non-judgment processing is performed by using the stored numerical value information of the hit random number counter C1.

The value of the random number that is won in the win/loss determination process is stored in the main ROM 64 as a win/loss table. As the win/loss table, first win/loss tables 495 and 496 are provided in association with the hold information on the first special view side, and second win/loss tables 497 and 498 are associated with the hold information on the second special view side. It is provided. Further, in the present embodiment, there are a high-probability mode and a low-probability mode in which the probability of being a jackpot result is relatively high or low, as win/win lottery modes.

FIG. 234(a) is an explanatory diagram for explaining the first hit/miss table 495 at the time of low probability, which is referred to when the hold determination processing is performed on the holding information on the first special map side in the low probability mode. FIG. 234(c) is an explanatory diagram for explaining the first hit/miss table 496 at the time of high probability, which is referred to when the hit/miss determination processing is performed on the pending information on the first special map side in the high probability mode. ) Is an explanatory diagram for explaining the second hit/miss table 497 at the time of low probability, which is referred to when the hold determination processing on the second special map side is held in the low probability mode, and FIG. 234( d) is It is explanatory drawing for demonstrating the 2nd hit/miss table 498 at the time of a high probability referred when performing a hit/miss determination process about the holding information by the side of a 2nd special figure in a high probability mode.

As shown in FIGS. 234(a) to 234(d), similar to the 64th embodiment, there are a big hit result, a small hit result, and a miss result as the result of the hit/miss determination processing. The jackpot result is a win/loss result that can be a trigger to shift to the opening/closing execution mode in which a plurality of round games are executed, and a trigger to shift to the win/loss lottery mode and the support mode. The small hit result is a win/loss result that does not trigger the shift to the win/win lottery mode and the support mode while triggering the shift to the open/close execution mode in which the special electric winning device 416 is controlled to open/close. The disengagement result is a win/fail result that does not trigger the shift of the opening/closing execution mode and further does not trigger the shift of the win/loss lottery mode and the support mode.

As shown in FIG. 234(a), a large hit result, a small hit result, and a miss result are set in the first hit/miss table 495 when the probability is low. Further, although the pachinko machine 10 has the setting states of “setting 1” to “setting 6”, a higher setting value has a higher probability of a jackpot result, and a higher setting value has a lower probability of a deviation result. Is set. On the other hand, the probability of a small hit result is set to be the same regardless of "Setting 1" to "Setting 6".

Specifically, the lowest setting value "Setting 1" is set to 50 as the number of pieces of numerical value information of the winning random number counter C1 which is a big hit result, and the numerical value of the winning random number counter C1 which is a small hit result. 1000 is set as the number of information, and 8950 is set as the number of numerical value information of the random number counter C1 which is a deviation result. Moreover, 52 pieces are set as the number of pieces of numerical information of the hit random number counter C1 which is a big hit result, in the "setting 2" which is a setting value one step higher than the "set 1", and the hit random number which is a small hit result is set. The number of numerical value information of the counter C1 is set to 1000, and the number of numerical value information of the random number counter C1 which is a deviation result is set to 8948. Moreover, 54 pieces are set as the number of pieces of numerical value information of the hit random number counter C1 which is a big hit result, in the "setting 3" which is a set value one step higher than the "set 2", and the hit random number which is a small hit result is set. The number of numerical value information of the counter C1 is set to 1000, and the number of numerical value information of the random number counter C1 which is a deviation result is set to 8946. Further, in "Setting 4", which is a setting value one step higher than "Setting 3", 56 pieces are set as the number of numerical value information of the hit random number counter C1 which is a big hit result, and the hit random number which is a small hit result is set. The number of numerical value information of the counter C1 is set to 1000, and the number of numerical value information of the random number counter C1 which is a deviation result is set to 8944. Further, "setting 5" which is a setting value one step higher than "setting 4" is set with 58 pieces of numerical information of the hit random number counter C1 which is a big hit result, and the random number which is a small hit result is set. The number of numerical value information of the counter C1 is set to 1000, and the number of numerical value information of the random number counter C1 which is a deviation result is set to 8942. Further, in the "setting 6" which is the highest setting value, 60 pieces are set as the number of pieces of numerical value information of the hit random number counter C1 which is a big hit result, and the number of pieces of numerical value information of the hit random number counter C1 which is a small hit result is set. Is set as 1000, and 8940 is set as the number of numerical value information of the random number counter C1 which is the result of deviation.

As shown in FIG. 234(b), a large hit result, a small hit result and a miss result are set in the first hit/miss table 496 at the time of high probability as the judgment result of the hit/miss judgment. Further, although the pachinko machine 10 has the setting states of “setting 1” to “setting 6”, a higher setting value has a higher probability of a jackpot result, and a higher setting value has a lower probability of a deviation result. Is set. On the other hand, the probability of a small hit result is set to be the same regardless of "Setting 1" to "Setting 6".

Specifically, 500 is set as the number of pieces of numerical value information of the hit random number counter C1 which is a big hit result in the "setting 1" which is the lowest setting value, and the numerical value of the hit random number counter C1 which is a small hit result. The number of pieces of information is set to 1000, and the number of pieces of numerical value information of the random number counter C1 which is the result of deviation is set to 8500 pieces. Further, 520 pieces are set as the number information of the hit random number counter C1 which is a big hit result in the "setting 2" which is a setting value one step higher than the "set 1", and the hit random number which is a small hit result is set. The number of pieces of numerical information of the counter C1 is set to 1000, and the number of pieces of numerical information of the random number counter C1 which is a deviation result is set to 8480. In addition, 540 pieces are set as the number of numerical value information of the hit random number counter C1 which is a big hit result in the "setting 3" which is a setting value one step higher than that of the "set 2", and the hit random number which is a small hit result is set. The number of numerical value information of the counter C1 is set to 1000, and the number of numerical value information of the random number counter C1 which is a deviation result is set to 8460. In addition, 560 is set as the number of pieces of numerical information of the hit random number counter C1 which is a big hit result, in the "setting 4" which is a setting value one step higher than that of the "set 3". The number of numerical value information of the counter C1 is set to 1000, and the number of numerical value information of the random number counter C1 which is a deviation result is set to 8440. Also, 580 pieces are set as the number of pieces of numerical value information of the hit random number counter C1 which is a big hit result, in the "setting 5" which is a setting value one step higher than that of the "set 4", and the hit random number which is a small hit result is set. The number of pieces of numerical information of the counter C1 is set to 1000, and the number of pieces of numerical information of the random number counter C1 which is a deviation result is set to 8420. In addition, 600 is set as the number information of the hit random number counter C1 which is a big hit result in the "setting 6" which is the highest setting value, and the number information of the hit random number counter C1 which is a small hit result is set. Is set as 1000, and 8400 is set as the number of numerical value information of the random number counter C1 that results in the deviation.

In "Setting 1", the probability that a jackpot result will be triggered by the holding information on the side of the first special map is 1/200 in the low-probability mode, and 1/20 of that in the high-probability mode. Is. In “Setting 2”, the probability that a jackpot result will be triggered by the holding information on the side of the first special map is about 1/192 in the low-probability mode, and about 10 times that in the high-probability mode. /19.2. In "Setting 3", the probability that a big hit result is triggered by the holding information on the side of the first special map is about 1/185 in the low probability mode, and about 1 times 10 times that in the high probability mode. /18.5. In "Setting 4", the probability that a jackpot result will be triggered by the holding information on the first special map side is about 1/179 in the low-probability mode, and about 1 times 10 times that in the high-probability mode. /17.9. In “Setting 5”, the probability that a jackpot result will be triggered by the holding information on the side of the first special map is about 1/172 in the low-probability mode, and about 1 times 10 times that in the high-probability mode. /17.2. In “Setting 6”, the probability that a jackpot result will be triggered by the holding information on the side of the first special map is about 1/167 in the low-probability mode, and about 1 times 10 times that in the high-probability mode. /16.7. In other words, the probability that a jackpot result will be triggered by the holding information on the side of the first special map in any of "Setting 1" to "Setting 6" is higher in the high probability mode than in the low probability mode. 10 times more.

On the other hand, the probability that the small hit result is triggered by the hold information on the side of the first special view is 1/10, which is the same regardless of any of "setting 1" to "setting 6". Further, the probability of a small hit result triggered by the pending information on the side of the first special diagram is 1/10, which is the same in both the low-probability mode and the high-probability mode. That is, the probability of a small hit result triggered by the hold information on the first special map side is constant regardless of the setting state and the winning/winning lottery mode. Further, the probability that a small hit result is triggered by the holding information on the side of the first special map is higher than the probability that a big hit result is obtained irrespective of the set state and the winning/winning lottery mode. However, when the holding information on the side of the first special map is used as an opportunity, the probability that the result of the release is the highest is the highest regardless of the setting state and the win/loss lottery mode. In addition, the probability of a miss result when the holding information on the first special map side is used as a trigger is higher than the combination probability of the big hit result and the small hit result regardless of the setting state and the win/loss lottery mode. ..

Note that the numerical information of the hit random number counters C1 that is a big hit result may be set so as to be aggregated so as to be a serial number. It may be configured to have. Further, the numerical value information of the hit random number counters C1 which is a small hit result may be set so as to be aggregated so as to be a serial number. It may be configured to have.

As shown in FIG. 234(c), the big hit result, the small hit result, and the miss result are set in the second hit/miss table 497 at the time of low probability as the result of the hit/miss judgment processing. Further, although the pachinko machine 10 has the setting states of “setting 1” to “setting 6”, a higher setting value has a higher probability of a jackpot result, and a higher setting value has a lower probability of a deviation result. Is set. On the other hand, the probability of a small hit result is set to be the same regardless of "Setting 1" to "Setting 6".

Specifically, the lowest setting value "Setting 1" is set to 50 as the number of pieces of numerical value information of the winning random number counter C1 which is a big hit result, and the numerical value of the winning random number counter C1 which is a small hit result. 9400 pieces are set as the number of pieces of information, and 550 pieces are set as the number of pieces of numerical value information of the random number counter C1 which is a deviation result. Moreover, 52 pieces are set as the number of pieces of numerical information of the hit random number counter C1 which is a big hit result, in the "setting 2" which is a setting value one step higher than the "set 1", and the hit random number which is a small hit result is set. The number of numerical information of the counter C1 is set to 9400, and the number of numerical information of the random number counter C1 which is a deviation result is set to 548. Moreover, 54 pieces are set as the number of pieces of numerical value information of the hit random number counter C1 which is a big hit result, in the "setting 3" which is a set value one step higher than the "set 2", and the hit random number which is a small hit result is set. The number of numerical value information of the counter C1 is set to 9400, and the number of numerical value information of the random number counter C1 which is a deviation result is set to 546. Further, in "Setting 4", which is a setting value one step higher than "Setting 3", 56 pieces are set as the number of numerical value information of the hit random number counter C1 which is a big hit result, and the hit random number which is a small hit result is set. The number of numerical information of the counter C1 is set to 9400, and the number of numerical information of the random number counter C1 which is a deviation result is set to 544. Further, "setting 5" which is a setting value one step higher than "setting 4" is set with 58 pieces of numerical information of the hit random number counter C1 which is a big hit result, and the random number which is a small hit result is set. The number of numerical value information of the counter C1 is set to 9400, and the number of numerical value information of the random number counter C1 which is a deviation result is set to 542. Further, in the "setting 6" which is the highest setting value, 60 pieces are set as the number of pieces of numerical value information of the hit random number counter C1 which is a big hit result, and the number of pieces of numerical value information of the hit random number counter C1 which is a small hit result is set. Is set as 9400, and 540 is set as the number of pieces of numerical value information of the random number counter C1 that results in a deviation.

As shown in FIG. 234(d), a large hit result, a small hit result, and a miss result are set in the second hit/miss table 498 at the time of high probability as the result of the hit/miss judgment processing. Further, although the pachinko machine 10 has the setting states of “setting 1” to “setting 6”, a higher setting value has a higher probability of a jackpot result, and a higher setting value has a lower probability of a deviation result. Is set. On the other hand, the probability of a small hit result is set to be the same regardless of "Setting 1" to "Setting 6".

Specifically, 500 is set as the number of pieces of numerical value information of the hit random number counter C1 which is a big hit result in the "setting 1" which is the lowest setting value, and the numerical value of the hit random number counter C1 which is a small hit result. 9400 pieces are set as the number of pieces of information, and 100 pieces are set as the number of pieces of numerical value information of the random number counter C1 which is a deviation result. Further, 520 pieces are set as the number information of the hit random number counter C1 which is a big hit result in the "setting 2" which is a setting value one step higher than the "set 1", and the hit random number which is a small hit result is set. The number of numerical value information of the counter C1 is set to 9400, and the number of numerical value information of the random number counter C1 which is a deviation result is set to 80. In addition, 540 pieces are set as the number of numerical value information of the hit random number counter C1 which is a big hit result in the "setting 3" which is a setting value one step higher than that of the "set 2", and the hit random number which is a small hit result is set. The number of numerical value information of the counter C1 is set to 9400, and the number of numerical value information of the random number counter C1 which is a deviation result is set to 60. In addition, 560 is set as the number of pieces of numerical information of the hit random number counter C1 which is a big hit result, in the "setting 4" which is a setting value one step higher than that of the "set 3". The number of numerical value information of the counter C1 is set to 9400, and the number of numerical value information of the random number counter C1 which is a deviation result is set to 40. In addition, 580 pieces are set as the number of pieces of numerical value information of the hit random number counter C1 which is a big hit result, in the "setting 5" which is a setting value one step higher than that of the "set 4". The number of numerical value information of the counter C1 is set to 9400, and the number of numerical value information of the random number counter C1 which is a deviation result is set to 20. In addition, 600 is set as the number information of the hit random number counter C1 which is a big hit result in the "setting 6" which is the highest setting value, and the number information of the hit random number counter C1 which is a small hit result is set. Is set to 9,400, and the number of numerical value information of the random number counter C1 which is a deviation result is 0.

In "Setting 1", the probability that a jackpot result will be triggered by the holding information on the side of the second special map is 1/200 in the low-probability mode, and 1/20 of that in the high-probability mode. Is. In "Setting 2", the probability of a jackpot result triggered by the holding information on the second special map side is about 1/192 in the low-probability mode, and about 10 times that in the high-probability mode. /19.2. In "Setting 3", the probability of a jackpot result triggered by the holding information on the side of the second special map is about 1/185 in the low-probability mode, and about 1 times 10 times that in the high-probability mode. /18.5. In “Setting 4”, the probability that a jackpot result will be triggered by the holding information on the side of the second special map is about 1/179 in the low-probability mode, and about 10 times that in the high-probability mode. /17.9. In "Setting 5", the probability that a jackpot result will be triggered by the holding information on the side of the second special map is about 1/172 in the low-probability mode, and about 1 times 10 times that in the high-probability mode. /17.2. In "Setting 6", the probability that a jackpot result will be triggered by the holding information on the side of the second special map is about 1/167 in the low-probability mode, and about 1 times 10 times that in the high-probability mode. /16.7. In other words, the probability that a jackpot result will be triggered by the holding information on the second special map side in any of "Setting 1" to "Setting 6" is higher in the high probability mode than in the low probability mode. 10 times more. In addition, the probability of a jackpot result when the combination of the same combination of the setting state and the win/loss lottery mode is compared is triggered by the holding information on the first special map side and the holding information on the second special map side. It is the same as when.

On the other hand, the probability of a small hit result triggered by the hold information on the side of the second special map is about 1/1.06, which is the same regardless of which of "Setting 1" to "Setting 6". In addition, the probability that a small hit result is triggered by the hold information on the second special figure side is 1/1.06, which is the same in both the low probability mode and the high probability mode. In other words, the probability of a small hit result triggered by the hold information on the second special map side is constant regardless of the setting state and the winning/winning lottery mode. The probability that a small hit result is triggered by the holding information on the second special figure side is higher than the probability that a small hit result is triggered by the holding information on the first special figure side. Further, the probability that the small hit result is triggered by the holding information on the side of the second special map is higher than the probability that the big hit result is obtained irrespective of the set state and the win/loss lottery mode. When the holding information on the side of the second special map is used as an opportunity, the probability of the small hit result is higher than the probability of the miss result regardless of the setting state and the win/loss lottery mode. Furthermore, the probability of a small hit result when the holding information on the second special map side is used as a trigger is higher than the combination probability of the big hit result and the miss result regardless of the setting state and the win/loss lottery mode. ..

Note that the numerical information of the hit random number counters C1 that is a big hit result may be set so as to be aggregated so as to be a serial number. It may be configured to have. Further, the numerical value information of the hit random number counters C1 which is a small hit result may be set so as to be aggregated so as to be a serial number. It may be configured to have.

As described above, the higher the set value, the higher the probability that the jackpot result will be, regardless of whether the holding information on the first special map side is the trigger or the holding information on the second special map side is the trigger. The higher the set value, the more advantageous it is for the player. In addition, the opening and closing execution mode is a period in which the increase amount of the player's ball per unit time is the largest, and the probability of the jackpot result that triggers the transition of the opening and closing execution mode varies according to the set value, It is possible to increase the player's attention to the set value.

In addition, in a configuration in which the probability of a jackpot result in the high-probability mode is higher than that in the low-probability mode, the probability of a jackpot result in the high-probability mode regardless of any of “Setting 1” to “Setting 6”. Is a certain number of times (specifically 10 times) higher than the probability of a big hit result in the low probability mode, which is a number larger than “1”. This makes it possible to keep the fluctuation rate of the probability of a jackpot result between the low-probability mode and the high-probability mode constant in any setting state.

In addition, the probability of a jackpot result when the combination of the same combination of the setting state and the win/loss lottery mode is compared is triggered by the holding information on the first special map side and the holding information on the second special map side. It is the same as when. As a result, it is possible to prevent a difference in the probability of occurrence of the jackpot result between when the holding information on the first special diagram side is used as an opportunity and when the holding information on the second special figure side is used as an opportunity. ..

Further, when the holding information on the side of the first special map is used as an opportunity, the probability of being a small hit result is the same regardless of any of "Setting 1" to "Setting 6", and the winning/losing lottery mode is the low probability mode and It is the same in any of the high probability modes. Further, when the holding information on the side of the second special map is used as a trigger, the probability of being a small hit result is the same regardless of any of "Setting 1" to "Setting 6", and the winning/discarding lottery mode is a low probability mode and It is the same in any of the high probability modes. This makes it possible for the player to limit his or her attention to the jackpot result in order to infer the set value, making it difficult to infer the set value.

On the other hand, the probability of being a small hit result is higher in the case of being triggered by the holding information of the second special figure side than in the case of being triggered by the holding information of the first special figure side. As a result, the frequency of occurrence of the small hit result depending on whether the game times triggered by the holding information on the first special map side are executed or the game times triggered by the holding information on the second special map side are executed. Can be different.

Further, in the first hit/miss table 495, 496, the number of pieces of numerical value information of the hit random number counter C1 assigned to the deviating result is larger than the number of pieces of numerical value information of the hit random number counter C1 assigned to the small hit result. In the configuration, the variation in the probability of the jackpot result due to the set value is absorbed by the variation in the number of numerical information of the hit random number counter C1 assigned to the deviating result. The number of pieces of numerical value information of the random number counter C1 assigned to the deviation result is the largest. As a result, it is possible to reduce the probability variation amount of the deviation result due to the setting value for absorbing the probability variation amount of the jackpot result due to the setting value. Therefore, when the holding information on the side of the first special map is used as an opportunity, it is possible to limit the target of attention to the jackpot result in order for the player to infer the setting value, which makes it difficult to infer the setting value. It will be possible.

Further, the number of pieces of numerical value information of the hit random number counter C1 assigned to the outlier result is smaller than the number of pieces of numerical value information of the hit random number counter C1 assigned to the small hit result in the second hit/miss tables 497 and 498. In the configuration, the variation in the probability of the jackpot result due to the set value is absorbed by the variation in the number of numerical information of the hit random number counter C1 assigned to the outlier result. Then, in the case of "setting 6" in which the combination probability of the big hit result and the small hit result is the highest, and in the high probability mode, the hit/miss determination process is performed on the pending information on the second special map side. There is a 0% chance that the result will be off. As a result, in the case of "setting 6" and in the high probability mode, the combination probability of the big hit result and the small hit result in the situation where the hit determination processing is performed on the pending information on the second special map side is appropriately increased. It becomes possible.

Next, the type counter C2 will be described. The type counter C2 is configured to be sequentially incremented by 1 within the range of 0 to 29, and then returned to "0" after reaching the maximum value. The type counter C2 is regularly updated, and is stored in the special figure holding area 451 of the main side RAM 65 at the timing when the game ball wins the first operating unit 412 or the second operating unit 413. Then, the type determination processing is performed using the stored value of the type counter C2.

The type determination process using the type counter C2 is performed when the jackpot result is obtained in the hit/miss determination process. On the other hand, when the small hit result is obtained in the hit determination processing, the type determination processing is not performed. That is, in the present embodiment, a plurality of types of big hit results are set, whereas only one type of small hit result is set. When the jackpot result is selected in the hit/miss determination process, the type of jackpot result is selected using the type table 499 and the type counter C2 stored in the main ROM 64 in advance. Hereinafter, the content of each type of jackpot result and the content of the small hit result will be described.

FIG. 235(a) is referred to in order to sort the types of jackpot results when the jackpot result is selected in the hit/miss determination process triggered by the hold information on the first special figure side or the hold information on the second special figure side. It is an explanatory view for explaining a type table 499. In addition, FIG. 235(b) is an explanatory diagram for explaining each content of a plurality of types of big hit results and the content of one type of small hit result.

The type table 499 is referred to when the jackpot result is selected in the hit determination process triggered by the hold information for the first special figure, and is also hit in the hit determination process triggered by the hold information for the second special figure. Referenced when the result is selected. That is, in the case where the jackpot result is selected in the hit determination process triggered by the hold information for the first special figure, and when the jackpot result is selected in the hit determination process triggered by the hold information for the second special figure In either case, the same type table 499 is referenced.

As shown in FIG. 235(a), the type table 499 includes 6R normal jackpot results, 6R high-accuracy jackpot results, and 16R high-accuracy jackpot results. Then, the numerical information of the type counter C2 of "0 to 10" corresponds to the 6R normal jackpot result, the numerical information of the type counter C2 of "11 to 26" corresponds to the 6R high-precision jackpot result, and " The numerical information of the type counter C2 of "27 to 29" corresponds to the 16R high-precision jackpot result. That is, when the jackpot result is selected in the hit/miss determination process, the 6R regular jackpot result is selected with a probability of 11/30, the 6R high-precision jackpot result is selected with a probability of 16/30, and the probability of 3/30. The 16R high-precision jackpot result is selected with.

When the 6R normal jackpot result is obtained, a round game occurs 6 times in the subsequent opening/closing execution mode as shown in FIG. 235(b). After the opening/closing execution mode is finished, the low probability mode is set regardless of the win/loss lottery mode before the opening/closing execution mode is started, and the high-frequency support mode is set regardless of the support mode before the opening/closing execution mode is started. .. However, this high-frequency support mode ends when the total number of game times triggered by the hold information on the first special map side and the game times triggered by the hold information on the second special map side are executed 50 times. Then, it shifts to the low frequency support mode.

In the round game, as in the 64th embodiment, the number of times the special electric prize winning device 416 is opened and closed is the upper limit number, and a predetermined upper limit winning number of game balls is won in the special electric prize winning device 416. A game that continues until either one of the conditions is met. In this embodiment, the special electric prize winning device 416 is opened and closed once in one round game, and the open duration in each round game is set to 29 seconds. Further, the upper limit number of winnings to the special electric winning device 416 is set to 10. In the situation where the firing operation device 28 is operated by the player, the game ball firing mechanism 27 is drive-controlled so that one game ball is fired toward the game area PA in 0.6 seconds, so that a round game is performed. The opening continuation period of is set to a time longer than the product of the firing cycle of the game ball and the maximum winning number of one round game. Therefore, in each round game, it can be expected that the special electric prize winning device 416 will win the game balls of the upper limit number or more.

When the 6R high accuracy jackpot result is obtained, the round game occurs 6 times in the subsequent opening/closing execution mode as shown in FIG. 235(b). Further, after the opening/closing execution mode ends, the high probability mode is set regardless of the win/loss lottery mode before the opening/closing execution mode is started, and the high-frequency support mode is set regardless of the support mode before the opening/closing execution mode is started. .. These high-probability mode and high-frequency support mode continue until the next big hit result game time ends. However, the high probability mode and the high frequency support mode are not limited to this, but will end when the number of times the game times are executed reaches the end reference number, but the end reference number will result in a big hit. The high probability mode and the high frequency support mode may be configured to continue until the game time that is the next big hit result is substantially ended because the number of times is extremely large compared to the probability.

When the 16R high-accuracy jackpot result is obtained, a round game occurs 16 times in the subsequent opening/closing execution mode as shown in FIG. 235(b). Therefore, the 16R high-accuracy jackpot result is the most advantageous jackpot result at least in terms of the number of round games to be executed. After the opening/closing execution mode is finished, the high probability mode is set regardless of the win/loss lottery mode before the opening/closing execution mode is started, and the low-frequency support mode is set regardless of the support mode before the opening/closing execution mode is started. .. These high-probability mode and low-frequency support mode continue until the next big hit result game time is over. However, the present invention is not limited to this, and these high-probability mode and low-frequency support mode will end when the number of times the game is executed reaches the end reference number, but the end reference number will result in a big hit. Since the number of times is very large compared to the probability, the high probability mode and the low frequency support mode may be configured to continue until the game time that is the next big hit result is substantially finished.

When the small hit result is obtained, as shown in FIG. 235(b), the special electric prize winning device 416 is opened once in the subsequent opening/closing execution mode. This one opening time ends when 2 seconds elapse or one of the conditions that the number of winnings to the special electric prize winning device 416 has reached 10 is satisfied. In this case, as described above, in the situation where the firing operation device 28 is being operated by the player, the game ball firing mechanism 27 is configured so that one game ball is fired toward the game area PA in 0.6 seconds. Since the driving is controlled, the opening continuation period of the opening time is set to a time shorter than the product of the firing cycle of the game ball and the maximum winning number of the opening time. Therefore, basically, the special electric prize winning device 416 does not receive more than the maximum winning number of game balls in the opening time, and the special electric prize winning device 416 is closed after the opening duration of 2 seconds elapses. .. Further, even if a small hit result occurs, the win/loss lottery mode and the support mode are maintained before the opening/closing execution mode.

As described above, the small hit result can be selected in the hit/miss determination process regardless of whether the holding information on the first special drawing side is triggered or the holding information on the second special drawing side is triggered. However, the probability that the small hit result is selected is higher when the holding information on the second special figure side is used as an opportunity than when the holding information on the first special figure side is used as an opportunity. More specifically, when the holding information on the side of the second special map is used as an opportunity, the probability that the small hit result is selected in the hit determination processing is higher than the combination probability of the big hit result and the miss result. When the holding information on the side of the first special map is used as a trigger, the probability that the deviating result is selected is higher than the probability that the small hit result is selected in the hit determination processing. Therefore, in the high-frequency support mode in which the winning frequency to the second operating unit 413 is high, the probability of a small hit per unit firing number is higher than in the low-frequency support mode. However, the expected number of gaming balls in which a prize is awarded to the special electric prize winning device 416 when a small hit result is triggered by the holding information on the second special map side is lower in the low frequency support mode than in the high frequency support mode. Many. The reason why such an event occurs will be described below.

FIG. 235(c) is an explanatory diagram for explaining the contents of the support mode. In either of the low frequency support mode and the high frequency support mode, the probability of being in the guidance state winning in the guidance state lottery for determining whether to control the guidance unit 432 of the second operating unit 413 to the guidance state is It is the same at 95%. However, the present invention is not limited to this, and the probability that the guided state is won may be substantially the same in the low frequency support mode and the high frequency support mode. The configuration may be such that there is a high probability that the guided state will be won.

The display continuation period of the variable display of the picture in the universal figure display portion 423a executed when the guidance state lottery is executed is 4 seconds in the low frequency support mode, while it is 4 seconds in the high frequency support mode. Is 0.1 seconds. While the variable display of the picture is being displayed on the universal figure display unit 423a, the guiding unit 432 of the second operating unit 413 is in the guided state even if the pending information on the universal figure side is held and stored in the universal figure holding area 455. It does not become. Then, when the guiding unit 432 of the second operating portion 413 is in the non-guided state, the game ball that has flowed into the right side area PA3 is located at the position of the special electricity winning device 416 that is located on the downstream side of the second operating portion 413. Can reach

When the guidance state is elected, the guidance state of the guidance unit 432 is executed in the low frequency support mode while the guidance unit 432 is in the guidance state only once over 2 seconds. In the frequency support mode, the guiding unit 432 is in the guiding state only once for 6 seconds. Note that the guiding state of the guiding unit 432 will end even when the number of winning prizes to the second operating unit 413 reaches the upper limit winning number of 10, but as described above, the firing operation device 28 causes the player to operate. In the situation where is operated by, the game ball firing mechanism 27 is drive-controlled so that one game ball is fired toward the game area PA in 0.6 seconds, so if it is a low frequency support mode, the guiding unit In the high frequency support mode, the guidance unit 432 is in the guidance state for 6 seconds while the guidance unit 432 is in the guidance state for 2 seconds.

With the above configuration, in the high-frequency support mode, the probability that the guiding unit 432 will win the guiding state is as high as 95%, and the game duration is 0.1 seconds in which the pattern display duration is 0.1 seconds. The firing period is shorter than the firing cycle of the above, and the guidance unit 432 is in the guidance state for 6 seconds in the guidance state. Further, as described above, the game ball flowing down the right side area PA3 basically wins the through winning part 414 and basically wins the second operating part 413 if the guiding unit 432 is in the guiding state. Therefore, in the high-frequency support mode, when the game ball is continuously emitted so as to flow down the right side area PA3, the guiding unit 432 is basically in the guiding state and the winning of the second operating portion 413 is achieved. The game ball does not flow into the downstream side of the second actuating portion 413 by being generated. Therefore, in the high-frequency support mode, although the winning of the second operating unit 413 occurs with high frequency, a small hit result occurs with the holding information on the second special map side as a trigger, and the special electric winning device 416 Even if the special electric prize winning device 416 is opened, the game ball does not reach a position where the special electric prize winning device 416 can enter the ball. By the way, since the number of game balls to be paid out is one even if the winning in the second operating unit 413 occurs, even if the winning in the second operating unit 413 occurs frequently in the high frequency support mode, the game is played. The number of game balls owned by the player does not increase.

On the other hand, in the low frequency support mode, there is a high probability that the guidance unit 432 wins the guidance state of 95%, and the display duration of the pattern on the universal figure display unit 423a is longer than the firing cycle of the game ball of 4 seconds. Time, and in the guidance state, the guidance unit 432 is in the guidance state for 2 seconds. Further, as described above, the game ball flowing down the right side area PA3 basically wins the through winning part 414 and basically wins the second operating part 413 if the guiding unit 432 is in the guiding state. Therefore, in the low frequency support mode, when the game ball is continuously emitted so as to flow down the right side area PA3, the guiding unit 432 is in the guiding state, so that the winning of the second operating portion 413 may occur. The game ball can reach the position of the special electric winning device 416 on the downstream side of the second operating unit 413. Therefore, in the low frequency support mode, the winning frequency to the second operating unit 413 is lower than in the high frequency support mode, but the small winning result is triggered by the holding information on the second special map side. A prize may be awarded to the special electric prize winning device 416 that is in the open state.

In the low-frequency support mode, the special special prize device 416 that is in the open state due to the small hit result triggered by the holding information on the second special map side may cause a prize to be generated. By making the display continuation period of the game times in the part 426 different between the case where the win/loss lottery mode is the low-probability mode and the case where it is the high-probability mode, the right region in the situation of the low-probability mode and the low-frequency support mode. Even if the firing operation is performed so as to flow down the PA3, the profit per unit time becomes extremely low, while the firing operation is performed so as to flow down the right side area PA3 in the high probability mode and the low frequency support mode. If done, the profit per unit time will be high. The configuration will be described below.

The fluctuation type counter CS is configured to be incremented by 1 in order within a range of 0 to 99, for example, and returns to "0" after reaching the maximum value. The variation type counter CS has a display continuation period (that is, a variation display period of the pattern) of the variable display of the symbols on the special figure display units 425 and 426 and a display continuation period of the symbol (that is, a variation display period of the symbol) on the symbol display device 424. Is used in the main CPU 63 to determine (these display continuation periods are also referred to as game continuation display continuation periods). The fluctuation type counter CS is repeatedly updated, and is acquired at the time of starting fluctuation display on the special figure display units 425 and 426 and determining the fluctuation pattern at the start of fluctuation of the symbol by the symbol display device 424. A setting mode of the display continuation period of the game time will be described with reference to the explanatory view of FIG. 236. The numbers “0 to 99” in FIG. 236 correspond to the value of the fluctuation type counter CS.

In the low probability mode, the mode of setting the display duration of the game times on the first special figure display unit 425 is the normal mode. In the normal setting mode, as shown in FIG. 236, if the result of the hit/miss determination processing is a disengagement result and it is a complete disengagement when the reach effect does not occur, the upper limit number (specifically, 4)) When a new game time is started in the situation where the 1st special map side hold information is stored, 2 seconds is selected as the game duration display duration, and the 1st special map hold When a new game time is started in a situation where the upper limit number of reserved information on the first special figure side is not stored in the area 452, any one of 10 seconds, 20 seconds and 30 seconds is displayed as the game time display continuation period. Is selected. Further, in the normal setting mode, the result of the win/loss judgment process is a miss result, but a reach effect occurs, but in the case of a miss reach, the result of the win/loss judgment process is a jackpot result and the result of the win/loss judgment process is a small hit result. In any of the cases, any one of 20 seconds, 30 seconds, 40 seconds, 50 seconds, 1 minute, 1 minute 30 seconds and 2 minutes is selected as the display duration of the game time. In this case, the jackpot result or the small hit result is easier to select a longer duration than the missed reach, and the average duration selected is also larger for the big hit result or the small hit result than for the missed reach. It's getting longer.

On the other hand, in the low-probability mode, the display continuation period of the game times on the second special figure display unit 426 is set to the long-term setting mode. In the long-term setting mode, the display continuation period of the selected game time is only one type, and the display continuation of that one type of game time is continued irrespective of the result determination result and the type determination result of the target game time. A period is selected. The display continuation period of the selected game time is 10 minutes. The display continuation period is longer than 2 minutes which is the display continuation period of the longest game time selected in the normal selection mode. As a result, in the low probability mode, the execution frequency of the game times on the second special figure display unit 426 becomes lower than the execution frequency of the game times on the first special figure display unit 425.

In the high probability mode, the setting mode of the display continuation period of the game time is different from that in the low probability mode. Specifically, in the high-probability mode, the display duration of the game times on the first special map display unit 425 is only one type regardless of whether or not the reach effect is generated when the win/fail judgment result is a miss result. Is a selection target, and even when the result of the hit determination is a big hit result or a small hit result, only one type is a selection target. In this case, the display duration of the game times in the case of a big hit result or a small hit result is set longer than the display duration of the game times in the case of a miss result, specifically, in the case of a miss result. While the display duration of the game times is 10 seconds, the display duration of the game times is 30 seconds when the big hit result or the small hit result is obtained.

In the high probability mode, the display duration of the game times on the second special figure display unit 426 is 0.5 seconds with a probability of 9/10 when the winning/decision result is a miss result or a small hit result. 1 minute and 30 seconds is selected with a probability of 10. On the other hand, in the case where the hit/no hit determination result is the jackpot result, only one type of 1 minute and 30 seconds is selected.

When the game time is executed in the second special figure display unit 426 in the high-probability mode and the small hit result is obtained, the display duration of the game time is 0.5 seconds with a high probability, The total period of the game times including the final stop period of the game times is 1 second. On the other hand, as described above, in the low frequency support mode, the display duration of the universal figure display unit 423a is 4 seconds, the guidance state of the guidance unit 432 is 2 seconds, and the second operation is performed. When a prize is awarded to the part 413, there is a high probability that a small hit result is obtained, and in the opening/closing execution mode when the small hit result is obtained, the special power winning device 416 is in the open state for 2 seconds. Then, in the high probability mode and the low frequency support mode, by performing the game ball launching operation so as to flow down the right side area PA3, the special prize winning device 416 which is in the open state as a result of the small hit result The frequency of winnings is higher than in other situations. Then, the winning frequency is determined by the number of game balls owned by the player when the game ball is ejected so as to flow down the right side area PA3 in the high probability mode and the low frequency support mode. The winning frequency is set to increase.

The trigger that causes the high probability mode to be the low frequency support mode is the 16R high-precision jackpot result, as described above. In addition, when the 16R high-precision jackpot result is reached, a high-probability mode and a low-frequency support mode are set until the jackpot result is newly generated after the opening/closing execution mode in which the round game occurs 16 times. Continues. Then, in the high probability mode and the low frequency support mode as described above, by performing the game ball launching operation so as to flow down the right side area PA3, the special prize winning which is in the open state as a result of the small hit result. The frequency at which a prize is generated in the device 416 is a high-probability mode and a low-frequency support mode. When a game ball is ejected so as to flow down the right side area PA3, a game owned by the player. The winning frequency is set to increase the number of balls. Therefore, as the number of game times in the second special figure display unit 426 executed until the new jackpot result is newly generated after the 16R high-precision jackpot result ends and the opening/closing execution mode ends, the game ball owned by the player increases. Will increase. Therefore, in this situation, the player expects that the jackpot result will not occur.

Even if a jackpot result occurs, if it is a 16R high-accuracy jackpot result, the situation that is the high probability mode and the low frequency support mode occurs again after the opening and closing execution mode in which the round game occurs 16 times is performed. It will be. Therefore, the player expects that the 16R high-accuracy jackpot result will be obtained if the jackpot result is obtained, while expecting that the jackpot result will not occur.

When the 6R high-accuracy jackpot result occurs, the state is the high-probability mode and the high-frequency support mode after the opening and closing execution mode in which the round game occurs 6 times. This situation will continue until a new jackpot result occurs. In this situation, as described above, by performing the shooting operation so that the game ball flows down the right side area PA3, the winning of the second operating portion 413 occurs frequently, but the opening state is triggered by the small hit result. Basically, no prize is awarded to the special electric prize winning device 416. Therefore, in this situation, the number of game balls owned by the player cannot be increased, but it is possible to generate the next jackpot result while not reducing the number too much. Therefore, in this situation, the player expects the jackpot result to occur early.

When the 6R normal jackpot result occurs, the situation is the low probability mode and the high frequency support mode after the opening and closing execution mode in which the round game occurs 6 times. Even in this situation, by performing a shooting operation so that the game balls flow down the right side area PA3, winnings to the second actuating portion 413 occur frequently, but the special electric prize is open due to the small hit result. Basically, no prize is awarded to the device 416. However, the win/no win lottery mode is a low-probability mode, and the high-frequency support mode ends and the low-frequency support mode is entered when the number of game times is 50. Therefore, in this situation, the player expects that the next big hit result will occur within a range where the player can play the game while not reducing the number of game balls owned by the player so much.

In the low probability mode and the low frequency support mode, even if the shooting operation is performed so that the game ball flows down the right side area PA3, the display duration of the game times on the second special map display unit 426 is extremely large. It will be a long 10 minutes. In this case, even if the shooting operation is performed so that the game ball flows down the right side area PA3, the efficiency of digesting the game is deteriorated. Therefore, the player performs the shooting operation so that the game ball flows down the left side area PA2. Become. By performing a firing operation so that the game ball flows down the left side area PA2, the game times in the first special figure display portion 425 are executed. In this case, the game duration display continuation period is in the normal setting mode as already described.

<First special map special power control process and second special map special power control process>
Next, the first special figure special power control processing and the second special figure special power control processing executed by the main CPU 63 will be described. In the present embodiment, unlike the 64th embodiment, the game time can be started in the second special view display unit 426 even when the game time is being executed in the first special view display unit 425, and Even when the game time is being executed on the second special figure display unit 426, the game time can be started on the first special figure display unit 425. Therefore, the first special figure special electric power control processing is set as the special electric figure special electric power control processing for the first special electric figure display portion 425, and the second special electric figure control processing for the second special electric figure display portion 426 is performed as the second special electric figure control processing. Tokuden control processing is set. The first special figure special power control process and the second special figure special power control process are executed instead of the special figure special power control process in the 64th embodiment, and the steps in the first timer interrupt process (FIG. 133). It is executed in S8913.

FIG. 237 is a flowchart showing the first special figure special power control process, and FIG. 238 is a flowchart showing the second special figure special power control process. The process of steps SF101 to SF111 in the first special figure special power control process and the process of steps SF201 to SF211 in the second special figure special power control process are the program for specific control and the data for specific control in the main CPU 63. Is executed using.

In the first special figure special electric power control process (FIG. 237), first, a process of acquiring the holding information on the first special figure side is executed (step SF101). In the acquisition process, when a prize is generated in the first operating unit 412, the number of pieces of reservation information on the first special figure side stored in the first special figure holding area 452 is the upper limit storage number (specifically, Under the condition that the number is less than 4), the storage process of the pending information on the first special map side is executed. In the storage processing, the numerical information of the hit random number counter C1, the type counter C2, and the reach random number counter C3 is used as the holding information on the first special figure side, and the first area 452a to the fourth area 452d of the first special figure holding area 452 are set. In the area where the reservation information on the side of the first special figure in FIG. When the pending information on the first special figure side is acquired, the display content of the first special figure pending display section 427 is updated according to the increase in the number of the pending information on the first special figure side this time. Data setting to do so. When the hold information on the first special figure side is acquired, the hold increase command is transmitted to the sound emission control device 81. As a result, the image for notifying the number of holding storages of the holding information on the first special figure side in the symbol display device 424 is updated in correspondence with the new acquisition of the holding information on the first special figure side.

In the second special figure special electric power control process (FIG. 238), first, a process of acquiring the holding information on the second special figure side is executed (step SF201). In the acquisition process, when a prize has been paid to the second operation unit 413, the number of pieces of the holding information on the second special figure side stored in the second special figure holding area 453 is the upper limit storage number (specifically, If the number is less than 4), the storage process of the reserved information on the second special figure side is executed. In the storage processing, the numerical information of the hit random number counter C1, the type counter C2, and the reach random number counter C3 is used as the holding information on the second special figure side, and the first area 453a to the fourth area 453d of the second special figure holding area 453 are set. It is stored in the area in which the digestion order is earlier among the areas in which the reservation information on the second special figure side in FIG. When the hold information on the second special figure side is acquired, the display content of the second special figure hold display section 428 is updated in accordance with the increase in the number of hold information on the second special figure side this time. Data setting to do so. Further, when the hold information on the second special figure side is acquired, the hold increase command is transmitted to the sound emission control device 81. As a result, the image for notifying the number of held storages of the holding information on the second special figure side in the symbol display device 424 is updated in correspondence with the new acquisition of the holding information on the second special figure side.

Returning to the description of the first special figure special power control process (FIG. 237) and the second special figure special power control process (FIG. 238), after executing the hold information acquisition process (step SF101 or step SF201), the main ROM 64 stores the information. The stored special figure special telephone address table is read (step SF101, step SF202). Then, in the case of the first special map special power control process (FIG. 237), the start address corresponding to the numerical information of the first special map special power counter is acquired from the special power distribution address table (step SF103), and the acquired start address The process jumps to the processing shown (step SF104). Further, in the case of the second special map special electric control process (FIG. 238), the start address corresponding to the numerical information of the second special figure special electric counter is acquired from the special special electric address table (step SF203), and the acquired start address is set. The process jumps to the indicated process (step SF204).

The first special figure special power counter is a counter for the main CPU 63 to know which of the processes of steps SF105 to SF111 in the first special figure special power control process (FIG. 237) should be executed. is there. The second special figure special power counter is a counter for the main CPU 63 to know which of the processes of steps SF205 to SF211 in the second special figure special power control process (FIG. 238) should be executed. is there. In the special figure special telephone address table, the start address in the program for executing each process of step SF105 to step SF111 is set in correspondence with the numerical information of the first special figure special telephone counter, and the second special figure special telephone counter is set. The start address in the program for executing each processing of step SF205 to step SF211 is set corresponding to the numerical information of.

If the value of the first special map special electric counter or the second special electric figure counter is "0", jump to the special figure variation start process of step SF105 or step SF205, the first special figure special electric counter or the second special figure When the value of the special electricity counter is "1", the process jumps to the special figure changing process of step SF106 or step SF206, and when the value of the first special figure special electricity counter or the second special electricity figure special electricity counter is "2" Jumps to the special figure finalizing process of step SF107 or step SF207, and when the value of the first special figure special electric counter or the second special figure special electric counter is "3", the special electric start processing of step SF108 or step SF208. If the value of the first special figure special electric counter or the second special figure special electric counter is "4", it jumps to the special electric open processing of step SF109 or step SF209, and the first special figure special electric counter or When the value of the 2 special map special electric counter is "5", the process jumps to the special electric power closing process of step SF110 or step SF210, and the value of the first special electric figure special electric counter or the second special electric figure special electric counter is "6". If there is, the process jumps to the special power termination process of step SF111 or step SF211. Hereinafter, each processing of step SF105 to step SF111 and step SF205 to step SF211 will be individually described.

<Special map fluctuation start processing>
First, the special figure variation start processing in steps SF105 and SF205 will be described with reference to the flowchart in FIG. 239. Note that the processes of step SF301 to step SF317 in the special figure variation start process are executed by using the program for specific control and the data for specific control in the main CPU 63.

In the special figure fluctuation start process, first, it is determined whether or not the process for the opening/closing execution mode is executed on the side that does not correspond to the current special figure special power control process (FIGS. 237 and 238) (step SF301). As described above, even if one of the first special figure display unit 425 and the second special figure display unit 426 is executing the game time, the other game time can be executed. In this case, step SF301 is executed, and when the process for the open/close execution mode is executed on the side that does not correspond to the current special figure special electric power control process (FIGS. 237 and 238), the processes after step SF302 are executed. Instead, the start of new game times is restricted. Thereby, in the situation where the opening/closing execution mode is executed triggered by the game time in one of the first special figure display unit 425 and the second special figure display unit 426, the game time in the other is not newly started. Regulated. Therefore, it is possible to increase the player's attention to the open/close execution mode. If this time is the special figure fluctuation start process in the first special figure special electric control process (FIG. 237), it is determined in step SF301 whether the value of the second special figure special electric counter is 3 or more, and 3 or more. If it is, the processing after step SF302 is not executed. If this time is the special figure fluctuation start process in the second special figure special electric control process (FIG. 238), it is determined in step SF301 whether or not the value of the first special figure special electric counter is 3 or more, and 3 or more. If it is, the processing after step SF302 is not executed.

When a negative determination is made in step SF301, it is determined whether or not the corresponding pending number is one or more (step SF302). If this time is the special figure variation start processing in the first special figure special electric power control processing (FIG. 237), it is determined whether or not one or more pieces of the first special figure holding information are stored in the first special figure holding area 452. However, if this time is the special figure fluctuation start process in the second special figure special electric control process (FIG. 238), whether or not one or more pieces of second special figure holding information are stored in the second special figure holding area 453. To judge.

When an affirmative determination is made in step SF302, data setting processing is executed (step SF303). In the data setting process, if this time is the first special map special electric power control process (FIG. 237), the data stored in the first area 452a of the first special map reservation area 452 is stored in the execution area 493 for the first special map. Moving. Then, the process of shifting the data stored in the storage area of the first special figure reservation area 452 is executed. This data shift processing sequentially shifts the data stored in the first to fourth areas 452a to 452d to the lower area side. Specifically, the data in each area is shifted in the order of the second area 452b→the first area 452a, the third area 452c→the second area 452b, the fourth area 452d→the third area 452c, and the fourth area 452d. Is cleared to "0". Further, in the data setting process, data setting is performed so that the display content of the first special figure reservation display unit 427 is updated in accordance with the decrease in the number of the reservation information on the first special figure side this time. Further, in the data setting process, the hold decrease command is transmitted to the voice emission control device 81. As a result, the image for notifying the number of held storages of the holding information on the first special figure side in the symbol display device 424 is updated in correspondence with the reduction of the holding information on the first special figure side.

In the data setting process, if this time is the second special figure special electric power control process (FIG. 238), the data stored in the first area 453a of the second special figure holding area 453 is changed to the execution area 494 for the second special figure. Moving. After that, the process of shifting the data stored in the storage area of the second special figure reservation area 453 is executed. In this data shift processing, the data stored in the first to fourth areas 453a to 453d are sequentially shifted to the lower area side. Specifically, the data in each area is shifted in the order of the second area 453b→the first area 453a, the third area 453c→the second area 453b, the fourth area 453d→the third area 453c, and the fourth area 453d. Is cleared to "0". In addition, in the data setting process, data setting is performed so that the display content of the second special figure reservation display unit 428 is updated in accordance with the decrease in the number of reservation information on the second special figure side this time. Further, in the data setting process, the hold decrease command is transmitted to the voice emission control device 81. As a result, the image for notifying the number of holding storages of the holding information on the second special figure side in the symbol display device 424 is updated in correspondence with the decrease of the holding information on the second special figure side.

After the data setting process is executed, the hit/miss determination process is executed (step SF304). In the win/loss determination process, when the current game time is triggered by the holding information on the first special map side, the first win/loss table 495, 496 (FIG. 4) corresponding to the current set values of the pachinko machine 10 and the win/loss lottery mode (FIG. 234(a) and FIG. 234(b)) is read from the main ROM 64. Then, the numerical information about the hit random number counter C1 is read out from the holding information on the side of the first special figure that triggered the start of the game this time, and the read numerical information is stored in the first hit/miss table 495, 496. By collating, it is specified whether the result of the hit determination processing this time is a big hit result, a small hit result, or a miss result. On the other hand, in the win/loss determination process, when the current game time is triggered by the hold information on the second special map side, the second win/loss table 497, 498 corresponding to the current set values of the pachinko machine 10 and the win/loss lottery mode. (See FIGS. 234(c) and 234(d)) is read from the main ROM 64. Then, the numerical information about the hit random number counter C1 is read out from the holding information on the side of the second special map that has triggered the start of the game this time, and the read numerical information is sent to the second hit/miss table 497, 498. By collating, it is specified whether the result of the hit determination processing this time is a big hit result, a small hit result, or a miss result.

When the result of the hit determination processing is the jackpot result (step SF305: YES), the type determination processing is executed (step SF306). In the type determination process, the type table 499 shown in FIG. 235(a) is read from the main ROM 64. If the hold information on the first special map side is the trigger for the current game, the numerical information about the type counter C2 is read out from the hold information on the first special map side and the second special map side is held. When the information is the trigger for the current game, the numerical information about the type counter C2 is read out from the holding information on the second special map side. Then, the read numerical value information about the type counter C2 falls within the numerical range of any type of jackpot result among the 6R normal jackpot result, the 6R high-accuracy jackpot result, and the 16R high-accuracy jackpot result set in the type table 499. Identify if it is supported.

After executing the type determination process, "1" is set to the flag of the main RAM 65 corresponding to the type of the jackpot result identified in the type determination process (step SF307). The state of the flag to which "1" is set is cleared to "0" when the open/close execution mode ends.

After that, the stop result setting process for the jackpot result is executed (step SF308). Specifically, information on the stop mode of the pattern to be finally stopped and displayed in the current game game on the side of the first special map display unit 425 and the second special map display unit 426 that is the execution target of the game game. From the stop result table for jackpot results stored in advance in the main ROM 64, and the specified information is stored in the main RAM 65. In this jackpot result stop result table, the types of the stop modes of the patterns stopped and displayed on the first special figure display unit 425 or the second special figure display unit 426 are set differently for each type of jackpot result. In step SF308, the main RAM 65 stores information on the stop mode of the design according to the type of the jackpot result identified in step SF306. It should be noted that the stop mode of the pattern may be set in a one-to-one correspondence with each jackpot result, or a plurality of types of stop modes of the pattern may be set for at least some of the jackpot results. A method of selecting a stop result for a jackpot result in which stop patterns of a plurality of types of patterns are set is arbitrary, but the stop result may be selected according to the value of the type counter C2, for example.

When the result of the hit determination processing is the small hit result (step SF309: YES), "1" is set to the flag of the main RAM 65 corresponding to the small hit result (step SF310). The state of the flag to which "1" is set is cleared to "0" when the opening/closing execution mode ends.

After that, the stop result setting process for the small hit result is executed (step SF311). Specifically, the information on the stop mode of the pattern to be finally stopped and displayed in the first special figure display unit 425 or the second special figure display unit 426 is read from the main ROM 64, and the read information is read. It is stored in the main RAM 65. The information on the pattern mode selected in this case is different from the information on the pattern mode selected in the case of the jackpot result.

When the result of the hit determination processing is neither the big hit result nor the small hit result (step SF305 and step SF309: NO), the stop result setting process for the deviation result is executed (step SF312). Specifically, information on the stop mode of the pattern to be finally stopped and displayed in the current game game on the side of the first special map display unit 425 and the second special map display unit 426 that is the execution target of the game game. From the stop result table for the disconnection result stored in advance in the main ROM 64, and the specified information is stored in the main RAM 65. The information on the pattern mode selected in this case is different from the information on the pattern mode selected in the case of the big hit result and the information of the pattern mode selected in the case of the small hit result.

After executing any one of the stop result setting processes, a display continuation period grasping process is executed (step SF313). In this processing, the numerical information of the fluctuation type counter CS is acquired, and the information of the current state and the display duration corresponding to the numerical information of the fluctuation type counter CS is selected in the mode shown in the explanatory diagram of FIG. 236.

After that, from the main ROM 64, the result of the present success/failure determination process and the type determination process, the current type of the random determination lottery mode, the type of the current support mode, and the variation command and the type command corresponding to the processing result of step SF313 are selected. To do. Then, the selected variation command and type command are transmitted to the voice emission control device 81 (step SF314). The sound emission control device 81 executes control for executing the game turn effect corresponding to the received variation command and type command.

After that, the variable display of the design is started on the side of the first special figure display unit 425 and the second special figure display unit 426 which is the target of the current game play (step SF315). The first special figure display section 425 and the second special figure display section are tables to be referred to by the main CPU 63 when the first special figure display section 425 or the second special figure display section 426 performs variable display of patterns. A variable display table for special drawings which is common to the 426 is stored in the main ROM 64 in advance. When the variable display of the pattern is executed in the first special figure display unit 425 or the second special figure display unit 426, the same variable display table is used regardless of the result of the hit/miss determination processing and the result of the type determination processing. It When the variable display of the pattern is performed on the first special figure display unit 425 or the second special figure display unit 426, the variable display of the pattern according to a predetermined pattern is repeated, but the variable display table for the special figure is not displayed. The control data for one rotation in the variable display of the pattern according to the predetermined pattern is set. Therefore, when the variable display of the pattern is performed on the first special figure display unit 425 or the second special figure display unit 426, the variable display table for special figures until the display continuation period of the game times determined in step SF313 elapses. Will be used repeatedly.

After that, the special display unit 429 is extinguished (step SF316). In the special display portion 429, when the opening/closing execution mode occurs, information corresponding to the number of round games that occur in the opening/closing execution mode is displayed. In other words, if the opening/closing execution mode is triggered by the 6R normal jackpot result or the 6R high-precision jackpot result, the special display unit 429 plays six round games when the opening/closing execution mode is started. The corresponding display is made. Further, when the opening/closing execution mode is triggered by the result of the 16R high-precision jackpot result, when the opening/closing execution mode is started, a display corresponding to 16 round games is displayed on the special display portion 429. Be seen. When the opening/closing execution mode is triggered by the result of the small hit result, a display corresponding to the small hit result is displayed on the special display unit 429 when the opening/closing execution mode is started. In the above-described configuration, the display on the special display portion 429 started when the opening/closing execution mode is started by executing the turning-off processing of the special display portion 429 in step SF316 of the special figure variation start processing is the opening/closing execution mode concerned. Is ended when a new game time is started after the end of. Then, the special display portion 429 is maintained in the off state until a new opening/closing execution mode occurs.

After that, if the current process corresponds to the first special map special power control process (FIG. 237), the value of the first special map special power counter is incremented by 1, and the current process is the second special map special power control process (FIG. If it corresponds to FIG. 238), the value of the second special figure special power counter is incremented by 1 (step SF317). Since the value of the special figure special power counter when the special figure fluctuation start process is executed is “0”, the value of the special figure special power counter that is the addition target by adding 1 is It becomes "1" corresponding to steps SF106 and SF206).

<Processing during special map change>
Next, the special figure changing process executed in step SF106 of the first special figure special electric control process (FIG. 237) and step SF206 of the second special figure special electric control process (FIG. 238) will be described.

In the case where the display continuation period of this game time has not elapsed, and when it is the update timing of the display contents of the special view display units 425, 426 which are the execution targets of this game time, Data setting for updating the display contents of the special figure display portions 425 and 426 is performed by referring to the variable display table. As a result, the display contents of the patterns on the special figure display portions 425 and 426, which are the objects of the game play this time, are updated to the display contents in the next order. In the main RAM 65, a first display order counter that is referred to in order to derive the display contents of the picture from the variable display table for the special picture at the time of updating the picture in the first special picture display unit 425. It is provided. Further, the main RAM 65 has a second display order counter which is referred to in order to derive the display contents of the picture from the variable display table for the special picture at the time when the picture is updated in the second special figure display unit 426. It is provided.

The mode at the time of starting the variable display of the pattern on the special figure display portions 425 and 426 and the updating mode of the variable display of the pattern are performed in a fixed mode regardless of the result of the hit/miss determination process and the result of the type determination process. It is carried out in a fixed manner regardless of the contents of the effect for game diversion on the symbol display device 424. For example, when a predetermined number of times of update occur, the display content of the pattern makes one round and the display pattern in which the display order is constant is repeatedly performed, and when the display continuation period of the game time has passed, Regardless of the order in which the display patterns are displayed, the stop result determined at the start of the game is displayed. This makes it possible to simplify the processing configuration for controlling the display of the special figure display units 425 and 426.

On the other hand, when the display continuation period of the game time has elapsed, the information on the stop mode of the picture of the special figure display portions 425, 426 stored in the main RAM 65 at the start of the game time is read and the stop mode of the picture is also read. The special figure display parts 425 and 426, which are the objects of the current game, are displayed and controlled so that. As a result, in the special figure display portions 425 and 426 which are the execution targets of the current game time, the pattern corresponding to the result of the success/failure determination process and the result of the type determination process of the current game time is displayed. The variable display is stopped. The mode of the pattern stopped and displayed in the special figure display parts 425 and 426 is maintained until the next variable display of the pattern is started in the special figure display parts 425 and 426 regardless of whether it is in the open/close execution mode. To be done. Further, the information of the final stop period (for example, 0.5 sec) is set in the timer counter of the main RAM 65. As a result, the measurement of the final stop period is started.

After that, the final stop command is transmitted to the voice emission control device 81. When receiving the final stop command from the main CPU 63, the sound emission control device 81 transmits the final stop command to the display control device 82. When the final stop command is received from the voice emission control device 81, the display control device 82 reads the display pattern table for stopping and displaying the combination of the stop symbols in the current game time over the final stop period. As a result, a combination of stop symbols corresponding to the current game time is stopped and displayed on the symbol display device 424 over the final stop period.

After that, if the current process corresponds to the first special map special power control process (FIG. 237), the value of the first special map special power counter is incremented by 1, and the current process is the second special map special power control process (FIG. If it corresponds to FIG. 238), the value of the second special map special electric counter is incremented by 1. Since the value of the special figure special electric counter when the special figure changing process is executed is "1", the value of the special figure special electric counter which is the addition target by adding 1 is the special figure finalizing process ( It is “2” corresponding to steps SF107 and SF207).

<Processing during special map confirmation>
Next, referring to the flowchart of FIG. 240, regarding the special figure finalizing process executed in step SF107 of the first special figure special electric control process (FIG. 237) and step SF207 of the second special figure special electric control process (FIG. 238). While explaining. Note that the processes of step SF401 to step SF409 in the special figure finalizing process are executed by using the program for specific control and the data for specific control in the main CPU 63.

When the final stop period has elapsed and the current game number corresponds to the jackpot result (step SF401 and step SF402: YES), the jackpot setting process is executed (step SF403). In the jackpot setting process, the special display unit 429 is display-controlled so that the display corresponding to six round games is started when the jackpot result of this time is the 6R normal jackpot result or the 6R high-precision jackpot result. Data setting for. Further, in the setting processing for the big hit, data for controlling the display of the special display portion 429 so that the display corresponding to the 16 round game is started when the result of the big hit this time is the 16R high-precision big hit result. Make settings.

When the final stop period has elapsed and the current game number corresponds to the small hit result (step SF401 and step SF404: YES), the small hit setting process is executed (step SF405). In the setting process for small hits, data setting for display control of the special display unit 429 is performed so that the display corresponding to the small hit result is started.

When the process of step SF403 or step SF405 is executed, the value of the special figure special power counter on the side not corresponding to the current special figure special power control process (FIGS. 237 and 238) is cleared to "0" (step SF406). As a result, even if the execution control of the game times is performed in the special figure special power control processing (FIGS. 237 and 238) on the side that does not correspond to the current special figure special power control processing (FIGS. 237 and 238), the game is controlled. The times are forcibly ended. In other words, in the situation where both the first special figure display portion 425 and the second special figure display portion 426 are executing the game times, when one game time that results in a big hit or a small hit is over, the other The game time will also be ended on the way. After that, the ending process of the other game time is executed (step SF407). In the ending process, the special figure display portions 425 and 426 on the side where the game times are forcibly ended are displayed in correspondence with the deviation result.

After that, if the current process corresponds to the first special map special power control process (FIG. 237), the value of the first special map special power counter is incremented by 1, and the current process is the second special map special power control process (FIG. If it corresponds to FIG. 238), the value of the second special figure special power counter is incremented by 1 (step SF408). Since the value of the special figure special power counter when the special figure finalizing process is executed is “2”, the value of the special figure special power counter which is the addition target by adding 1 is the special power start process (step SF108). , Step SF208) becomes “3”.

If the current game time is a miss result (step SF404: NO), if the current process corresponds to the first special map special electric control process (FIG. 237), the value of the first special map special electric counter is set to " 0" is cleared, and if the current process corresponds to the second special figure special electric power control process (FIG. 238), the value of the second special figure special electric counter is cleared to "0" (step SF409). As a result, the value of the special figure special electricity counter becomes "0" corresponding to the special figure variation start process (steps SF105 and SF205).

<Special train start processing>
Next, the special electric power starting processing executed in step SF108 of the first special electric power control processing (FIG. 237) and step SF208 of the second special electric power control processing (FIG. 238) will be described.

In the special electric power start process, before the start of the opening period, the measurement of the opening period (for example, 4 seconds) is started and the opening command is transmitted to the voice emission control device 81. When receiving the opening command, the sound emission control device 81 executes the emission control of the display emission section 53 and the sound output control of the speaker section 54 so that the opening effect is executed. Further, the sound emission control device 81 transmits an opening command to the display control device 82. When the display control device 82 receives the opening command, the display control device 82 executes the display control of the symbol display device 424 so that the opening effect is executed.

In the special electric power start processing, if the opening period has elapsed, if this time is triggered by one of the jackpot results, the round counter provided in the main RAM 65 corresponds to the number of times the round game is executed in the opening/closing execution mode this time. Set the information to be set. The round counter is a counter for specifying the number of remaining round games in the main CPU 63 in the open/close execution mode, and the value of the round counter is decremented by 1 each time a round game is executed. Further, the timer counter of the main RAM 65 is set with information (specifically 29 seconds) of the open duration of the round game, and the special prize winning device 416 in one round game is set in the prize counter provided in the main RAM 65. The information (specifically, "10") corresponding to the upper limit number of winning prizes is set. On the other hand, if this time is triggered by the small hit result, "1" is set to the round counter provided in the main RAM 65. Further, the timer counter provided in the main RAM 65 is set with information (specifically, 2 seconds) on the opening duration of the small hit result, and the prize winning counter provided in the main RAM 65 is provided with the special prize winning result in the small hit result. Information (specifically, “10”) corresponding to the maximum number of winning prizes to the device 416 is set.

After that, a special electric open setting process is executed. In the opening setting process, the output of the drive signal to the drive unit 416c for special electric power is started so that the special electric prize winning device 416 is in the open state. After that, if the current process corresponds to the first special map special power control process (FIG. 237), the value of the first special map special power counter is incremented by 1, and the current process is the second special map special power control process (FIG. If it corresponds to FIG. 238), the value of the second special map special electric counter is incremented by 1. Since the value of the special map special electric power counter when the special electric power start processing is executed is “3”, the value of the special electric power special electric counter which is the addition target by adding 1 is the special electric power open process (step SF109, It becomes "4" corresponding to step SF209).

<Processing during opening of special train>
Next, the special electric power releasing processing which is executed in step SF109 of the first special electric power control processing (FIG. 237) and step SF209 of the second special electric power control processing (FIG. 238) will be described.

In the special electric open process, the closing setting process is executed when the opening continuation period of the special electric prize winning device 416 has elapsed or when the special electric prize winning device 416 has won the upper limit winning number of game balls. In the closing setting process, the output of the drive signal to the drive unit 416c for special electricity is stopped so that the special electricity winning device 416 is closed. Then, the value of the round counter of the main RAM 65 is decremented by 1.

When the value of the round counter after subtracting 1 is not "0", information (specifically, 2 seconds) corresponding to the closing duration is set in the timer counter of the main RAM 65. After that, if the current process corresponds to the first special map special power control process (FIG. 237), the value of the first special map special power counter is incremented by 1, and the current process is the second special map special power control process (FIG. If it corresponds to FIG. 238), the value of the second special map special electric counter is incremented by 1. Since the value of the special map special electric counter when the special electric open processing is executed is “4”, the value of the special electric special counter that is the addition target by adding 1 is the special electric closing processing (step SF110). , Step SF210) corresponding to “5”.

When the value of the round counter after subtracting 1 is “0”, information (specifically, 10 seconds) corresponding to the ending period is set in the timer counter of the main RAM 65. Further, the ending command is transmitted to the sound emission control device 81. When the sound emission control device 81 receives the ending command, the sound emission control device 81 executes the light emission control of the display light emitting unit 53 and the sound output control of the speaker unit 54 so that the ending effect is executed. Further, the audio emission control device 81 transmits an ending command to the display control device 82. When receiving the ending command, the display control device 82 executes the display control of the symbol display device 424 so that the ending effect is executed. Thereafter, if the current process corresponds to the first special map special power control process (FIG. 237), the value of the first special map special power counter is incremented by 2, and the current process is the second special map special power control process (FIG. 237). If it corresponds to FIG. 238), the value of the second special figure special power counter is incremented by 2. Since the value of the special map special electric counter when the special electric open processing is executed is “4”, the value of the special electric figure special electric counter which is the addition target by adding 2 is the special electric end processing (step SF111, It becomes “6” corresponding to step SF211).

<Processing during closing of special train>
Next, the special electric power closing during processing executed in step SF110 of the first special electric power control processing (FIG. 237) and step SF210 of the second special electric power control processing (FIG. 238) will be described.

If the closing continuation period has elapsed, the timer counter of the main RAM 65 is set with information on the opening continuation period of the round game (specifically, 29 seconds), and the winning counter of the main RAM 65 is used for one round game. The information (specifically, "10") corresponding to the upper limit winning number to the special electric prize winning device 416 in is set. Then, the special electric winning device 416 is opened by executing the special electric open setting process. Thereafter, if the current process corresponds to the first special map special power control process (FIG. 237), the value of the first special map special power counter is decremented by 1, and the current process is the second special map special power control process (FIG. 237). If it corresponds to FIG. 238), the value of the second special figure special power counter is decremented by 1. Since the value of the special map special power counter is “5” when the special power closing process is executed, the value of the special power special counter that has been subtracted by 1 is the special power opening process (step SF109). , Step SF209) corresponding to “4”.

<Tokuden termination processing>
Next, the special electric power ending processing executed in step SF111 of the first special electric power control processing (FIG. 237) and step SF211 of the second special electric power control processing (FIG. 238) will be described.

When the ending period has elapsed, the transition process at the end of the open/close execution mode is executed. In the transition processing, if the opening/closing execution mode this time is the 6R normal jackpot result, the win/loss lottery mode is set to the low-probability mode and the support mode is set to the high-frequency support mode. In addition, when the total number of game times reaches 50 times, the information for ending the high frequency support mode is also set. When the trigger of the opening/closing execution mode this time is the 6R high-precision jackpot result, the win/loss lottery mode is set to the high-probability mode and the support mode is set to the high-frequency support mode. When the opening/closing execution mode this time is the 16R high-accuracy jackpot result, the win/loss lottery mode is set to the high-probability mode and the support mode is set to the low-frequency support mode. On the other hand, if the opening/closing execution mode this time is the result of the small hit, the process for changing the win/loss lottery mode and the support mode from before the start of the opening/closing execution mode is not executed.

After that, if the current process corresponds to the first special map special power control process (FIG. 237), the value of the first special map special power counter is cleared to “0”, and the current process is the second special power control device. If it corresponds to the processing (FIG. 238), the value of the second special figure special power counter is cleared to “0”. As a result, the value of the special figure special electricity counter becomes "0" corresponding to the special figure variation start process (steps SF105 and SF205).

According to this embodiment described in detail above, the following excellent effects are exhibited.

In the hit determination processing for the hold information on the first special map side, it is determined that the number of pieces of numerical information of the hit random number counter C1 is determined to be a big hit result. It is absorbed by the variation of the number of numerical information of the random number counter C1 which is determined to be a deviation result in the processing. As a result, a big hit result is obtained in the hit/fail judgment processing for the hold information on the first special figure side while not affecting the probability of a small hit result in the hold judgment processing for the hold information on the first special figure side. It is possible to change the probability.

The number of numerical value information of the hit random number counter C1 which is determined to be a small hit result in the hit/miss determination process for the pending information on the first special figure side is the same regardless of the set value. This makes it possible to make the probability that the small hit result is selected in the hit determination processing for the hold information on the first special figure side constant for all the set values. In addition, even if the probability that the small hit result is selected in the hold determination process for the holding information on the first special map side is constant in this way, Because the variation of each setting value of the probability that the jackpot result is selected is absorbed by the variation of the probability that the outlier result is selected, the jackpot result is selected in the hit/miss determination process for the pending information on the first special map side. It is possible to set the probability of being performed according to the set value.

The number of numerical value information of the random number counter C1 which is determined to be a deviation result in the hold determination process for the pending information on the first special figure side is the largest regardless of any of the set values. As a result, the deviation result is selected in the hit/fail judgment processing for the hold information on the first special figure side by the variation in each setting value of the probability that the jackpot result is selected in the hit judgment processing for the hold information on the first special figure side. Even if it is configured to absorb by the fluctuation amount of the probability, the probability that a deviation result will occur in the hold information on the first special map side will not cause a large fluctuation between the setting values of multiple stages. It becomes possible to do.

Whether or not the variation in each set value of the number of pieces of numerical value information of the hit random number counter C1 which is determined to be a big hit result in the hold determination processing for the hold information on the second special figure side is the right/off determination for the hold information on the second special figure side. It is absorbed by the variation of the number of numerical information of the random number counter C1 which is determined to be a deviation result in the processing. As a result, a big hit result is obtained in the hit/fail judgment processing for the hold information on the second special figure side while not affecting the probability of a small hit result in the hold information judgment processing for the second special figure side. It is possible to change the probability.

The number of numerical value information of the hit random number counter C1 which is determined to be a small hit result in the hit/miss determination processing for the hold information on the second special figure side is the same regardless of the set value. This makes it possible to make the probability that the small hit result is selected in the hit determination processing for the hold information on the second special figure side constant for all the set values. Even if the probability that the small hit result is selected in the hold determination process for the holding information on the second special figure side is constant in this way, Since the variation of each setting value of the probability that the jackpot result is selected is absorbed by the variation of the probability that the outlier result is selected, the jackpot result is selected in the hit/miss judgment process for the pending information on the second special map side. It is possible to set the probability of being performed according to the set value.

In the situation where the setting value that is the situation that the jackpot result of the hold information on the second special map side is the highest, the setting value is “setting 6” and the lottery mode is the high probability mode, The number of numerical value information of the random number counter C1 which is determined to be a deviation result by the determination processing of the pending information on the special figure side is 0. As a result, the variation in each set value of the probability of a jackpot result in the hold determination process for the holding information on the second special drawing side is determined by the variation of each setting value. In a configuration that absorbs fluctuations, it is possible to maximize the probability of a jackpot result in the situation where the probability of a jackpot result is highest as described above.

The probability that a small hit result is obtained in the win/loss determination process for the hold information on the first special map side is the same regardless of whether the set value or the win/loss lottery mode is set. This makes it possible to prevent the player from guessing both the set value and the winning/winning lottery mode from the probability of a small hit result.

The probability that a small hit result is obtained not only in the hit determination processing for the holding information on the first special map side but also in the hit determination processing for the holding information on the second special drawing side is set value and win/win lottery mode respectively. Are also the same. As a result, regardless of whether the winning information is for the holding information on the first special drawing side or the holding information is for the holding information on the second special drawing side, the set value and the winning/winning lottery mode are selected from the probability of the small hit result. It is possible to prevent the player from guessing both.

There is a difference between the probability that the small hit result is selected in the hit determination processing for the holding information on the first special drawing side and the probability that the small hit result is selected in the hit determination processing for the holding information on the second special drawing side. There is. As a result, the probability that a small hit result is obtained not only in the hit determination process for the holding information on the first special drawing side but also in the hit determination processing for the holding information on the second special drawing side depends on whether the set value or the win/win lottery mode is used. Even if there is the same structure, it is possible to cause a situation in which the probability of a small hit result is different.

Note that, instead of the configuration of the above-described embodiment, each of the numbers of numerical information of the hit random number counter C1 that is determined to be a jackpot result when the hit determination processing is performed on the pending information on the first special map side. The variation in the set value is absorbed by the variation in the number of numerical information of the hit random number counter C1 which is determined to be a small hit result when the hit determination processing is executed for the pending information on the first special map side. It may be configured to be.

Further, instead of the configuration of the above-described embodiment, each of the numbers of numerical information of the hit random number counter C1 which is determined to be a jackpot result when the hit/miss determination processing is executed for the pending information on the second special figure side. The fluctuation in the set value is absorbed by the fluctuation in the number of numerical information of the hit random number counter C1 which is determined to be the small hit result when the hit determination processing is executed for the hold information on the second special map side. It may be configured to be.

Further, the small hit result is selected when the winning/disapproval determination process is executed for the hold information on the first special map side, but instead of this, for the hold information on the first special map side. The small hit result may not be selected when the hit/miss determination processing is executed.

<70th Embodiment>
In this embodiment, the content of the win/loss table referred to in the win/loss determination processing is different from that in the 69th embodiment. The configuration different from that of the 69th embodiment will be described below. Note that the description of the same configuration as the 69th embodiment is basically omitted.

FIG. 241(a) is an explanatory diagram for explaining the first hit/miss table 495 at the time of low probability, which is referred to when the hold determination processing for the holding information on the first special map side is performed in the low probability mode. FIG. 241(b) is an explanatory diagram for explaining the first hit/miss table 496 at the time of high probability, which is referred to when the hit/miss determination processing is performed on the pending information on the first special map side in the high probability mode. ) Is an explanatory diagram for explaining the second hit/miss table 501 at the time of low probability, which is referred to when the hit/miss judgment processing is performed on the pending information on the second special figure side in the low probability mode, and FIG. 241(d) is It is explanatory drawing for demonstrating the 2nd hit/miss table 502 at the time of high probability referred when performing the hit/miss judgment process about the holding information on the 2nd special map side in a high probability mode.

As shown in FIGS. 241(a) and 241(b), the contents of the first win/loss table 495 at the low probability and the first win/loss table 496 at the high probability are the same as those in the 69th embodiment. On the other hand, the contents of the second probability table 501 at low probability shown in FIG. 241(c) and the second probability table 502 at high probability shown in FIG. 241(d) are different from those in the 69th embodiment. The second win/loss table 501 for the low probability and the second win/loss table 502 for the high probability will be described below.

As shown in FIG. 241(c), the big hit result, the small hit result, and the miss result are set in the second hit/miss table 501 at the low probability as the judgment result of the hit/miss judgment processing. Further, although the pachinko machine 10 has the setting states of “setting 1” to “setting 6”, a higher setting value has a higher probability of a jackpot result, and a higher setting value has a lower probability of a deviation result. Is set. On the other hand, the probability of a small hit result is set to be the same regardless of "Setting 1" to "Setting 6".

Specifically, the lowest setting value "Setting 1" is set to 50 as the number of pieces of numerical value information of the winning random number counter C1 which is a big hit result, and the numerical value of the winning random number counter C1 which is a small hit result. 9300 pieces are set as the number of pieces of information, and 650 pieces are set as the number of pieces of numerical value information of the random number counter C1 which is a deviation result. Moreover, 52 pieces are set as the number of pieces of numerical information of the hit random number counter C1 which is a big hit result, in the "setting 2" which is a setting value one step higher than the "set 1", and the hit random number which is a small hit result is set. 9300 is set as the number of numerical information of the counter C1, and 648 is set as the number of numerical information of the random number counter C1 which is a deviation result. Moreover, 54 pieces are set as the number of pieces of numerical value information of the hit random number counter C1 which is a big hit result, in the "setting 3" which is a set value one step higher than the "set 2", and the hit random number which is a small hit result is set. The number of numerical value information of the counter C1 is set to 9300, and the number of numerical value information of the random number counter C1 which is a deviation result is set to 646. Further, in "Setting 4", which is a setting value one step higher than "Setting 3", 56 pieces are set as the number of numerical value information of the hit random number counter C1 which is a big hit result, and the hit random number which is a small hit result is set. The number of numerical value information of the counter C1 is set to 9300, and the number of numerical value information of the random number counter C1 which is a deviation result is set to 644. Further, "setting 5" which is a setting value one step higher than "setting 4" is set with 58 pieces of numerical information of the hit random number counter C1 which is a big hit result, and the random number which is a small hit result is set. The number of numerical information of the counter C1 is set to 9300, and the number of numerical information of the random number counter C1 which is a deviation result is set to 642. Further, in the "setting 6" which is the highest setting value, 60 pieces are set as the number of pieces of numerical value information of the hit random number counter C1 which is a big hit result, and the number of pieces of numerical value information of the hit random number counter C1 which is a small hit result is set. Is set as 9300, and 640 is set as the number of pieces of numerical value information of the random number counter C1 that results in a deviation.

As shown in FIG. 241(d), the large hit result, the small hit result, and the miss result are set in the second hit/miss table 502 at the high probability as the judgment result of the hit/miss judgment processing. Further, although the pachinko machine 10 has the setting states of “setting 1” to “setting 6”, a higher setting value has a higher probability of a jackpot result, and a higher setting value has a lower probability of a deviation result. Is set. On the other hand, the probability of a small hit result is set to be the same regardless of "Setting 1" to "Setting 6".

Specifically, 500 is set as the number of pieces of numerical value information of the winning random number counter C1 which is a big hit result in the "setting 1" which is the lowest setting value, and the numerical value of the hit random number counter C1 which is a small hit result. 9300 is set as the number of pieces of information, and 200 is set as the number of pieces of numerical value information of the random number counter C1 which is a deviation result. Also, 520 is set as the number of pieces of numerical value information of the hit random number counter C1 which is a big hit result, in the "setting 2" which is a setting value one step higher than that of the "set 1", and the hit random number which is a small hit result is set. The number of numerical value information of the counter C1 is set to 9300, and the number of numerical value information of the random number counter C1 which is a deviation result is set to 180. Further, 540 pieces are set as the number of pieces of numerical value information of the hit random number counter C1 which is a big hit result, in the "setting 3" which is a setting value one step higher than that of the "set 2", and the hit random number which is a small hit result is set. The number of numerical value information of the counter C1 is set to 9300, and the number of numerical value information of the random number counter C1 which is a deviation result is set to 160. Also, 560 is set as the number of numerical value information of the hit random number counter C1 which is a big hit result, in the "setting 4" which is a setting value one step higher than the "set 3", and the hit random number which is a small hit result is set. The number of numerical value information of the counter C1 is set to 9300, and the number of numerical value information of the random number counter C1 which is a deviation result is set to 140. Also, 580 pieces are set as the number of pieces of numerical value information of the hit random number counter C1 which is a big hit result, in the "setting 5" which is a setting value one step higher than that of the "set 4", and the hit random number which is a small hit result is set. The number of numerical value information of the counter C1 is set to 9300, and the number of numerical value information of the random number counter C1 which is a deviation result is set to 120. Moreover, 600 is set as the number information of the hit random number counter C1 which is a big hit result in the "setting 6" which is the highest setting value, and the number information of the hit random number counter C1 which is a small hit result is set. Is set as 9300, and 100 is set as the number of pieces of numerical value information of the random number counter C1 which is the result of deviation.

In "Setting 1", the probability that a jackpot result will be triggered by the holding information on the side of the second special map is 1/200 in the low-probability mode, and 1/20 of that in the high-probability mode. Is. In "Setting 2", the probability of a jackpot result triggered by the holding information on the second special map side is about 1/192 in the low-probability mode, and about 10 times that in the high-probability mode. /19.2. In "Setting 3", the probability of a jackpot result triggered by the holding information on the side of the second special map is about 1/185 in the low-probability mode, and about 1 times 10 times that in the high-probability mode. /18.5. In “Setting 4”, the probability that a jackpot result will be triggered by the holding information on the side of the second special map is about 1/179 in the low-probability mode, and about 10 times that in the high-probability mode. /17.9. In "Setting 5", the probability that a jackpot result will be triggered by the holding information on the side of the second special map is about 1/172 in the low-probability mode, and about 1 times 10 times that in the high-probability mode. /17.2. In "Setting 6", the probability that a jackpot result will be triggered by the holding information on the side of the second special map is about 1/167 in the low-probability mode, and about 1 times 10 times that in the high-probability mode. /16.7. In other words, the probability that a jackpot result will be triggered by the holding information on the second special map side in any of "Setting 1" to "Setting 6" is higher in the high probability mode than in the low probability mode. 10 times more. In addition, the probability of a jackpot result when the combination of the same combination of the setting state and the win/loss lottery mode is compared is triggered by the holding information on the first special map side and the holding information on the second special map side. It is the same as when.

On the other hand, the probability of a small hit result triggered by the hold information on the side of the second special map is about 1/1.08, which is the same regardless of which of "Setting 1" to "Setting 6". In addition, the probability of a small hit result triggered by the holding information on the second special map side is 1/1.08, which is the same in both the low-probability mode and the high-probability mode. In other words, the probability of a small hit result triggered by the hold information on the second special map side is constant regardless of the setting state and the winning/winning lottery mode. The probability that a small hit result is triggered by the holding information on the second special figure side is higher than the probability that a small hit result is triggered by the holding information on the first special figure side. Further, the probability that the small hit result is triggered by the holding information on the side of the second special map is higher than the probability that the big hit result is obtained irrespective of the set state and the win/loss lottery mode. When the holding information on the side of the second special map is used as an opportunity, the probability of the small hit result is higher than the probability of the miss result regardless of the setting state and the win/loss lottery mode. Furthermore, the probability of a small hit result when the holding information on the second special map side is used as a trigger is higher than the combination probability of the big hit result and the miss result regardless of the setting state and the win/loss lottery mode. ..

Note that the numerical information of the hit random number counters C1 that is a big hit result may be set so as to be aggregated so as to be a serial number. It may be configured to have. Further, the numerical value information of the hit random number counters C1 which is a small hit result may be set so as to be aggregated so as to be a serial number. It may be configured to have.

According to the above configuration, the number of numerical value information of the hit random number counter C1 assigned to the deviating result is larger than the number of numerical value information of the hit random number counter C1 assigned to the small hit result in the second hit/miss tables 497 and 498. In the case where the number is smaller than the above, the variation in the probability of the jackpot result due to the set value is absorbed by the variation in the number of numerical information of the hit random number counter C1 assigned to the deviation result. In this case, if the combination probability of the big hit result and the small hit result is the highest, that is, “setting 6”, and the high probability mode is set, the success/failure determination process is performed on the pending information on the second special map side. Even in the case of being broken, there is a 1/100 chance of a failure result. With this, it is possible to select the disengagement result even in the situation where the hold information on the second special map side is judged to be right or wrong in the case of “setting 6” and the high probability mode. It will be possible.

<71st Embodiment>
In this embodiment, the content of the win/loss table referred to in the win/loss determination processing is different from that in the 69th embodiment. The configuration different from that of the 69th embodiment will be described below. Note that the description of the same configuration as the 69th embodiment is basically omitted.

FIG. 242(a) is an explanatory diagram for explaining the first hit/miss table 495 at the time of low probability, which is referred to when the hit/miss determination processing is performed on the pending information on the first special map side in the low probability mode. FIG. 242(c) is an explanatory diagram for explaining the first hit/miss table 496 at the time of high probability, which is referred to when the hit/miss determination processing is performed on the pending information on the first special map side in the high probability mode. 242) is an explanatory view for explaining the second hit/miss table 503 at the time of low probability which is referred to when the hit/miss judgment processing is performed on the pending information on the second special figure side in the low probability mode, and FIG. 242(d) is It is explanatory drawing for demonstrating the 2nd hit/miss table 504 at the time of high probability referred when performing the hit/miss judgment processing about the hold information on the 2nd special figure side in a high probability mode.

As shown in FIGS. 242(a) and 242(b), the contents of the first win/loss table 495 at the low probability and the first win/loss table 496 at the high probability are the same as in the 69th embodiment. On the other hand, the contents of the second probability table 503 at low probability shown in FIG. 242(c) and the second probability table 504 at high probability shown in FIG. 242(d) are different from those in the 69th embodiment. The second win/loss table 503 for the low probability and the second win/loss table 504 for the high probability will be described below.

As shown in FIG. 242(c), the big hit result, the small hit result, and the miss result are set in the second hit/miss table 503 at the low probability as the judgment result of the hit/miss judgment processing. In addition, although the pachinko machine 10 has the setting states of “setting 1” to “setting 6”, a higher setting value has a higher probability of a jackpot result, and a higher setting value has a lower probability of a jackpot result. Is set to be. On the other hand, the probability of the result of the deviation is set to be the same regardless of "Setting 1" to "Setting 6".

Specifically, the lowest setting value "Setting 1" is set to 50 as the number of pieces of numerical value information of the winning random number counter C1 which is a big hit result, and the numerical value of the winning random number counter C1 which is a small hit result. 9450 pieces are set as the number of pieces of information, and 500 pieces are set as the number of pieces of numerical value information of the random number counter C1 which is a deviation result. Moreover, 52 pieces are set as the number of pieces of numerical information of the hit random number counter C1 which is a big hit result, in the "setting 2" which is a setting value one step higher than the "set 1", and the hit random number which is a small hit result is set. 9448 is set as the number of numerical information of the counter C1, and 500 is set as the number of numerical information of the random number counter C1 which is a deviation result. Moreover, 54 pieces are set as the number of pieces of numerical value information of the hit random number counter C1 which is a big hit result, in the "setting 3" which is a set value one step higher than the "set 2", and the hit random number which is a small hit result. The number of numerical value information of the counter C1 is set to 9446, and the number of numerical value information of the random number counter C1 which is a deviation result is set to 500. Further, in "Setting 4", which is a setting value one step higher than "Setting 3", 56 pieces are set as the number of numerical value information of the hit random number counter C1 which is a big hit result, and the hit random number which is a small hit result is set. The number of numerical value information of the counter C1 is set to 9444, and the number of numerical value information of the random number counter C1 which is a deviation result is set to 500. Further, "setting 5" which is a setting value one step higher than "setting 4" is set with 58 pieces of numerical information of the hit random number counter C1 which is a big hit result, and the random number which is a small hit result is set. 9442 is set as the number of numerical information of the counter C1, and 500 is set as the number of numerical information of the random number counter C1 which is a deviation result. Further, 60 is set as the number of numerical information of the hit random number counter C1 which is a big hit result in the "setting 6" which is the highest setting value, and the number of numerical information of the hit random number counter C1 which is a small hit result is set. Is set as 9440, and 500 is set as the number of numerical value information of the hit random number counter C1 which is a deviation result.

As shown in FIG. 242(d), a large hit result, a small hit result, and a miss result are set in the second hit/miss table 504 at the time of high probability as the judgment results of the hit/miss judgment processing. In addition, although the pachinko machine 10 has the setting states of “setting 1” to “setting 6”, a higher setting value has a higher probability of a jackpot result, and a higher setting value has a lower probability of a jackpot result. Is set to be. On the other hand, the probability of the result of the deviation is set to be the same regardless of "Setting 1" to "Setting 6".

Specifically, 500 is set as the number of pieces of numerical value information of the hit random number counter C1 which is a big hit result in the "setting 1" which is the lowest setting value, and the numerical value of the hit random number counter C1 which is a small hit result. The number of pieces of information is set to 9000, and the number of pieces of numerical value information of the random number counter C1 which is a deviation result is set to 500. Further, 520 pieces are set as the number information of the hit random number counter C1 which is a big hit result in the "setting 2" which is a setting value one step higher than the "set 1", and the hit random number which is a small hit result is set. The number of numerical value information of the counter C1 is set to 8980, and the number of numerical value information of the random number counter C1 which is a deviation result is set to 500. In addition, 540 pieces are set as the number of numerical value information of the hit random number counter C1 which is a big hit result in the "setting 3" which is a setting value one step higher than that of the "set 2", and the hit random number which is a small hit result is set. The number of numerical information of the counter C1 is set to 8960, and the number of numerical information of the random number counter C1 which is a deviation result is set to 500. In addition, 560 is set as the number of pieces of numerical information of the hit random number counter C1 which is a big hit result, in the "setting 4" which is a setting value one step higher than that of the "set 3". The number of numerical information of the counter C1 is set to 8940, and the number of numerical information of the random number counter C1 which is a deviation result is set to 500. Also, 580 pieces are set as the number of pieces of numerical value information of the hit random number counter C1 which is a big hit result, in the "setting 5" which is a setting value one step higher than that of the "set 4", and the hit random number which is a small hit result is set. The number of numerical information of the counter C1 is set to 8920, and the number of numerical information of the random number counter C1 which is a deviation result is set to 500. Moreover, 600 is set as the number information of the hit random number counter C1 which is a big hit result in the "setting 6" which is the highest setting value, and the number information of the hit random number counter C1 which is a small hit result is set. Is set to 8900, and the number of pieces of numerical value information of the random number counter C1 which is a deviation result is 500.

In "Setting 1", the probability that a jackpot result will be triggered by the holding information on the side of the second special map is 1/200 in the low-probability mode, and 1/20 of that in the high-probability mode. Is. In "Setting 2", the probability of a jackpot result triggered by the holding information on the second special map side is about 1/192 in the low-probability mode, and about 10 times that in the high-probability mode. /19.2. In "Setting 3", the probability of a jackpot result triggered by the holding information on the side of the second special map is about 1/185 in the low-probability mode, and about 1 times 10 times that in the high-probability mode. /18.5. In “Setting 4”, the probability that a jackpot result will be triggered by the holding information on the side of the second special map is about 1/179 in the low-probability mode, and about 10 times that in the high-probability mode. /17.9. In "Setting 5", the probability that a jackpot result will be triggered by the holding information on the side of the second special map is about 1/172 in the low-probability mode, and about 1 times 10 times that in the high-probability mode. /17.2. In "Setting 6", the probability that a jackpot result will be triggered by the holding information on the side of the second special map is about 1/167 in the low-probability mode, and about 1 times 10 times that in the high-probability mode. /16.7. In other words, the probability that a jackpot result will be triggered by the holding information on the second special map side in any of "Setting 1" to "Setting 6" is higher in the high probability mode than in the low probability mode. 10 times more. In addition, the probability of a jackpot result when the combination of the same combination of the setting state and the win/loss lottery mode is compared is triggered by the holding information on the first special map side and the holding information on the second special map side. It is the same as when.

In "Setting 1", the probability of a small hit result triggered by the holding information on the side of the second special map is about 1/1.582 in the low probability mode, and about 1 in the high probability mode. It is 1/1.111. In “Setting 2”, the probability of a small hit result triggered by the holding information on the second special map side is about 1/1.0584 in the low-probability mode and about 1/1.084 in the high-probability mode. It is 1.113. In "Setting 3", the probability that a small hit result is triggered by the holding information on the second special map side is about 1/1.586 in the low probability mode, and about 1/1.0 in the high probability mode. It is 1.116. In "Setting 4", the probability of a small hit result triggered by the holding information on the second special map side is about 1/1.589 in the low probability mode, and about 1/1.0 in the high probability mode. 1.119. In "Setting 5", the probability of a small hit result triggered by the holding information on the side of the second special map is about 1/1.0591 in the low probability mode and about 1/1.0 in the high probability mode. It is 1.121. In "Setting 6", the probability of a small hit result triggered by the holding information on the second special map side is about 1/1.0593 in the low probability mode, and about 1/1.0 in the high probability mode. It is 1.124.

Note that the numerical information of the hit random number counters C1 that is a big hit result may be set so as to be aggregated so as to be a serial number. It may be configured to have. Further, the numerical value information of the hit random number counters C1 which is a small hit result may be set so as to be aggregated so as to be a serial number. It may be configured to have.

According to the above configuration, the number of values of the hit random number counter C1 assigned to the deviating result is larger than the number of values of the hit random number counter C1 assigned to the small hit result in the first hit/miss table 495, 496. In many configurations, the variation in the probability of the jackpot result due to the set value is absorbed by the variation in the number of numerical information of the hit random number counter C1 assigned to the deviation result. The number of numerical information of the hit random number counter C1 assigned to the deviation result is the largest regardless of the set value. As a result, it is possible to reduce the probability variation amount of the deviation result due to the setting value for absorbing the probability variation amount of the jackpot result due to the setting value. Therefore, when the holding information on the side of the first special map is used as an opportunity, it is possible to limit the target of attention to the jackpot result in order for the player to infer the setting value, which makes it difficult to infer the setting value. It will be possible.

Further, the number of pieces of numerical value information of the hit random number counter C1 assigned to the small hit result is larger than the number of pieces of numerical value information of the hit random number counter C1 assigned to the deviation result in the second hit/miss tables 503 and 504. In the configuration, the variation in the probability of the jackpot result depending on the set value is absorbed by the variation in the number of numerical information of the hit random number counter C1 assigned to the jackpot result. Further, the number of numerical value information of the hit random number counter C1 assigned to the small hit result is the largest regardless of the set value. As a result, it is possible to reduce the probability variation of the small hit result by the set value for absorbing the probability variation of the big hit result by the set value. Therefore, when the holding information on the side of the first special map is used as an opportunity, it is possible to limit the target of attention to the jackpot result because the player estimates the setting value, which makes it difficult to estimate the setting value. It will be possible.

<72nd Embodiment>
In this embodiment, the processing configuration when the supply of operating power is started is different from that in the 49th embodiment. Hereinafter, a configuration different from that of the 49th embodiment will be described. Note that the description of the same configuration as the 49th embodiment is basically omitted.

FIG. 243 is a front view of the game board 24 in the present embodiment.

Similar to the first embodiment, the inner rail portion 25 and the outer rail portion 26 are attached to the game board 24 so as to partition a part of the outer edge of the game area PA. The outer rail portion 26 constitutes a guide rail as guide means. The game ball launched from the game ball launch mechanism 27 (see FIG. 2) is guided to the upper part of the game area PA by the guide rail. Further, in the game area PA, like the first embodiment, the general winning opening 31, the special electricity winning device 32, the first operating opening 33, the second operating opening 34, the through gate 35, the variable display unit 36, the special drawing unit. 37 and a universal figure unit 38 are provided respectively.

Here, in the present embodiment, the movable body 512 is provided in the center frame 511 provided so as to surround the periphery of the symbol display device 41 in the variable display unit 36. The movable body 512 is connected to the movable body drive unit 513 via a link mechanism (not shown), and is driven when the movable body drive unit 513 is in the displacement state to move from the initial position in a predetermined direction. At the same time, the movable body drive unit 513 moves to return to the initial position by being brought into the return state. The operation of the movable body 512 can be visually recognized from the front of the pachinko machine 10 through the window panel 52. That is, the manner in which the movable body 512 operates can be visually recognized from the front of the pachinko machine 10 without requiring the opening operation of the gaming machine main body 12 and the front door frame 14.

Regarding the movable body 512 in detail, the movable body 512 is movable between an initial position and a movement limit position, and is arranged in front of the display surface 41a by moving from the initial position toward the movement limit position. Thus, the area facing the display surface 41a in front of the display surface 41a is wider than in the initial position. Specifically, at the initial position, the entire body is arranged outside the display surface 41a and inside the center frame 511, and the movable body 512 is not visible or visible when the display surface 41a is viewed from the front. It has a difficult structure. On the other hand, in the movement limit position, the entire body faces the display surface 41a from the front side, and the visibility of the movable body 512 is improved as compared with the case of the initial position, but the visibility of the display surface 41a is reduced. Become. The configuration is not limited to this, and the movable body 512 may be visually recognizable regardless of whether the movable body 512 is arranged at the initial position or at the movement limit position.

The movable body 512 is a movable ornamental body in which decoration is provided on a surface (that is, a surface facing the front of the gaming machine) that is visible to the player when the movable body 512 is arranged at the movement limit position, and a predetermined character. Although it has a form imitating (for example, “fish”), the specific form is arbitrary. The movement of the movable body 512 from the initial position to the movement limit position is performed in conjunction with the effect for game play on the display surface 41a, and returns to the initial position when the predetermined effect is completed. In this way, the movement of the movable body 512 is used to perform an effect that is integrated with the image effect on the display surface 41a.

In the pachinko machine 10, when the movable body 512 is moved from the initial position in the middle of the effect for game play (for example, during the reach), the open/close execution mode is compared to when the movable body 512 is not moved. The structure has high expectations for the transition to. However, the present invention is not limited to this, and in addition to or in place of the configuration, when the result of the winning/losing determination that the probability of winning/winning lottery after the opening/closing execution mode is high becomes the same in the production for game play, In a configuration that performs an effect as if promotion to high probability occurred during the open/close execution mode while stopping and displaying results that do not clearly indicate high probability such as a combination of symbols with even numbers As an effect, the movable body 512 may be moved from the initial position.

Next, the electrical configurations of the main controller 60 and the sound emission controller 81 will be described with reference to the explanatory diagram of FIG. 244.

The main controller 60 is provided with a main control board 61 as in the 49th embodiment, and the main control board 61 is provided with a main CPU 63, a main ROM 64, and a main ROM 64 as in the 49th embodiment. The MPU 62 including the main RAM 65 is provided. The main control board 61 is provided with the first to fourth notification display devices 201 to 204 as in the 49th embodiment. The display contents displayed on the first to fourth notification display devices 201 to 204 are the same as those in the 35th embodiment. Therefore, in the first to fourth notification display devices 201 to 204, when the supply of the operating power to the main CPU 63 is started, the check display is performed for the initial check period, and then the base value is set. A display for notifying is performed.

The first to fourth notification display devices 201 to 204 are provided side by side on the element mounting surface of the main control board 61 as in the eleventh embodiment (see FIG. 53). Each of the first to fourth notification display devices 201 to 204 is a segment display in which seven display segments by LEDs are arranged, but the display device is not limited to this, and a single multicolor emission type single display device is used. It may be a light emitting body, a liquid crystal display device, or an organic EL display. The first to fourth notification display devices 201 to 204 are installed so that their display surfaces face the direction in which the element mounting surface of the main control board 61 faces, and by the facing wall portion 60b of the board box 60a. Is covered. In this case, since the substrate box 60a is formed transparent, the display surfaces of the first to fourth notification display devices 201 to 204 housed in the substrate box 60a are visually observed from the outside of the substrate box 60a. It becomes possible. Further, the main controller 60 is mounted on the back surface of the resin base 21 so that the facing wall portion 60b facing the element mounting surface of the main control board 61 in the board box 60a faces the back of the pachinko machine 10, so that the gaming machine. When the main body 12 is opened to the front of the pachinko machine 10 with respect to the outer frame 11 and the back surface of the resin base 21 is exposed to the front of the pachinko machine 10, the first to fourth notification display devices 201 through the facing wall portion 60b. It is possible to visually check the display surfaces of 204.

As shown in FIG. 244, the audio emission control device 81 includes an audio emission control board 351. The sound emission side MPU 352 is mounted on the sound emission control board 351. The sound-light side MPU 352 includes a sound-light side ROM 354 and a sound-light side RAM 355 in addition to the sound-light side CPU 353 which is an arithmetic processing unit including a control unit and a calculation unit. In addition to the above-described elements, the sound/light side MPU 352 has an interrupt circuit, a timer circuit, a data input/output circuit, various counter circuits as a random number generator, and the like built therein.

The sound-light side ROM 354 is a memory such as a NOR flash memory and a NAND flash memory that does not require external power supply for storage, and is used as a read-only memory. The sound-light side ROM 354 stores various control programs executed by the sound-light side CPU 353 and fixed value data.

The sound-light side RAM 355 is a memory (that is, a volatile storage means) such as an SRAM and a DRAM that needs to be supplied with electric power from the outside to retain the storage, and is used for both reading and writing. The sound-light side RAM 355 is capable of random access and has a shorter read time than the sound-light side ROM 354 when compared with the same data capacity. The sound-light side RAM 355 temporarily stores various data and the like for the execution of the control program stored in the sound-light side ROM 354.

The MPU 62 of the main control device 60 is electrically connected to the input side of the sound/light side MPU 352, and the display light emitting unit 53, the speaker unit 54, the display control device 82, and the movable body are provided on the output side of the sound/light side MPU 352. The drive unit 513 is electrically connected. The sound-light side MPU 352 drives and controls the display light emitting section 53, the speaker section 54, and the movable body drive section 513, and also controls the display control apparatus 82 based on various commands received from the MPU 62 of the main control device 60. The display control device 82 executes the display control of the symbol display device 41 based on the command received from the sound-light side MPU 352. As a result, various effects and various notifications are executed by the symbol display device 41, the display light emitting section 53, the speaker section 54, and the movable body 512 in a situation where the game times and the opening/closing execution mode are executed.

Next, the main processing in this embodiment executed by the main CPU 63 will be described with reference to the flowchart in FIG. 245. Note that the processing of steps SF501 to SF529 in the main processing is executed using the program for specific control and the data for specific control in the main CPU 63.

First, power-on initialization processing is executed (step SF501). In the power-on initialization process, for example, a predetermined wait time (specifically, 1 second) elapses after the main process is started, and the process waits without proceeding to the next process. In the predetermined period for this weight, the operation start and initial setting of the symbol display device 41 are completed. Also, access to the main RAM 65 is permitted.

Then, the internal function register setting process is executed (step SF502). In the internal function register setting process, as in the 35th embodiment, the interrupt period of the first timer interrupt process (FIG. 133), which is a process that is activated by periodically interrupting the main process, is set to the first interrupt period. (Specifically, 4 ms), and the interrupt period of the second timer interrupt process (FIG. 134), which is a process that is periodically interrupted and activated with respect to the main process, is set from the first interrupt period. Is set to the second interrupt cycle (specifically, 2 milliseconds) which is a short cycle.

That is, in this embodiment, as in the 35th embodiment, the first timer interrupt processing (FIG. 133) and the second timer interrupt processing (FIG. 134) are performed so that the interrupt cycle becomes relatively short as the timer interrupt processing. And exist. Both the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134) are activated by interrupting the main process. The second timer interrupt process (FIG. 134) is activated by interrupting the first timer interrupt process (FIG. 133). On the other hand, the first timer interrupt process (FIG. 133) does not start by interrupting the second timer interrupt process (FIG. 134). In addition, when both the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134) are not executed, and when both the first interrupt cycle and the second interrupt cycle have passed, those cycles The second timer interrupt processing (FIG. 134) is started first regardless of the lapsed order of the above. In this respect, it can be said that the second timer interrupt process (FIG. 134) is a process that is activated prior to the first timer interrupt process (FIG. 133). However, the configuration is not limited to this, and the first timer interrupt process (FIG. 133) may be activated prior to the second timer interrupt process (FIG. 134).

In the internal function register setting process, the first interrupt period of the first timer interrupt process (FIG. 133) is set in a predetermined register of the main CPU 63, and the second interrupt period of the second timer interrupt process (FIG. 134) is set. It is set in a specific register of the side CPU 63. Further, in the internal function register setting process, in addition to the setting of the first and second interrupt cycles, the setting process of the numerical range of various counters such as the numerical range of the hit random number counter C1 is executed.

Then, "1" is set to the in-start-up processing flag provided in the work area 221 for specific control (step SF503). As in the 35th embodiment, the start-up processing flag is among the various processes set in the first timer interrupt process (FIG. 133) even if the first timer interrupt process (FIG. 133) is activated. While the power outage monitoring, the processing for updating various counters and the illegality monitoring are executed, the first timer interrupt processing (FIG. 133) should be terminated without executing the processing for advancing the game. This is a flag for specifying by the main CPU 63.

The start-up processing flag is set to "1" when the process at the start of supplying the operating power (step SF501 to step SF523) is started in the main process (FIG. 245), and the process at the start of supplying the operating power. “0” is cleared before (steps SF501 to SF523) are ended and residual processing (steps SF526 to SF529) is started. As in the 35th embodiment, in the first timer interrupt process (FIG. 133), when the start-up processing flag is set to "1", the processes of steps S8907 to S8920 are not executed. Therefore, in order to advance the game in the situation where the setting confirmation process (FIG. 246) or the set value update process (FIG. 247), which will be described later, is executed in the process (step SF501 to step SF523) at the time of starting the supply of the operating power. It is possible to prevent the processing of (1) from being executed. On the other hand, as described above, in the first timer interrupt processing (FIG. 133), even if the start-up processing flag is set to "1", by executing the processing of steps S8901 to S8905, the operating power is reduced. The power failure monitoring is executed even in the situation where the setting confirmation processing (FIG. 246) or the set value update processing (FIG. 247), which will be described later, is being executed among the processing (steps SF501 to SF523) at the start of supply of At the same time, the hit random number counter C1, the big hit type counter C2, the reach random number counter C3, and the random number initial value counter CINI are updated, and further fraud detection is executed.

In particular, even when the start-up processing flag is set to "1", the power failure information storage processing (step S8901) is executed, so that the operation power supply start processing (step SF501 to step SF523) is started. Even if a power outage occurs in the situation where the setting confirmation process (FIG. 246) or the set value update process (FIG. 247) described later is executed, it is possible to execute the power outage process for it. In the power failure process, similar to the thirty-fifth embodiment, “1” is set to the power failure flag provided in the specific control work area 221, and the checksum calculation process (FIG. 253) is executed to execute the process. Since the calculated checksum is stored in the work area 221 for specific control, it is possible to prevent the main RAM 65 from being identified as having an abnormality when the supply of operating power is restarted. As a result, when a power failure occurs during the setting confirmation processing (FIG. 246) or the setting value update processing (FIG. 247), the fact that the power failure has occurred during the setting related processing is supplied to the next operating power. It is possible to specify at the start.

Incidentally, in the situation where the setting confirmation process (FIG. 246) or the setting value update process (FIG. 247) is being executed, both the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134) are performed. Interrupts are not prohibited and can be interrupted at any timing. In this case, when the first timer interrupt process (FIG. 133) or the second timer interrupt process (FIG. 134) is activated in the setting confirmation process (FIG. 246) or the setting value update process (FIG. 247), The information on the return address of the main process (FIG. 245) for returning after the timer interrupt process that is the target of activation is saved in the stack area 222 for specific control, and the timer interrupt process is activated. Information of various registers of the main CPU 63 immediately before is saved in the stack area 222 for specific control. Then, when the timer interrupt process that is the activation target ends, the process returns to the process of the main process (FIG. 245) corresponding to the information of the return address saved in the stack area 222 for specific control, and The information saved in the stack area 222 for specific control is restored to various registers of the main CPU 63.

After setting the start-up processing flag to "1" in step SF503, it is determined whether the power failure flag provided in the specific control work area 221 is set to "1" (step SF504). .. When the power failure information storage processing (step S8901) of the first timer interrupt processing (FIG. 133) executes the power failure processing, the power failure flag is set to "1". The power outage flag is a flag for the main CPU 63 to specify whether or not the power outage process was appropriately performed at the previous power off time.

When the power failure flag is set to "1" (step SF504: YES), after the checksum calculation processing (FIG. 253) is executed as in the case of the power failure processing (step SF505), the calculated checksum is calculated. Is determined to be normal (step SF506). Although details will be described later, in the power failure process and the checksum calculation process in each of step SF505 (FIG. 253), the checksum is calculated for the specific control work area 221 and the specific control stack area 222. In step SF506, the specific control work area 221 and the specific control work area 221 which are calculated and stored in the specific control work area 221 in the power outage process executed immediately before the supply of the operating power to the main CPU 63 is stopped. The checksum of the stack area 222 for use in reading is read, and the read checksum is compared with the checksum calculated in step SF505. Then, it is determined whether the checksums match.

If the checksums match (step SF506: YES), is the setting value corresponding to the information stored in the setting reference area 341 (see FIG. 154) in the specific control work area 221 within the normal range? It is determined whether or not (step SF507). The setting reference area 341 is a storage area in which information for specifying the current setting value of the pachinko machine 10 by the main CPU 63 is stored as in the 45th embodiment. When the numerical information of “1” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 1”. When the numerical information of “2” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 2”. When the numerical information of “3” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 3”. When the numerical information of “4” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 4”. When the numerical information of “5” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 5”. When the numerical information of “6” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 6”. In step SF507, it is determined whether or not the setting value information stored in the setting reference area 341 is any of "1" to "6".

When a positive determination is made in all of step SF504, step SF506, and step SF507, it is determined whether or not "1" is set in the setting update display flag provided in the work area 221 for specific control (step SF508). .. The setting update display flag is a flag for the main CPU 63 to specify that the setting value update processing (FIG. 247) is being executed, as in the 35th embodiment, and the setting update display flag is “1”. When is set, a display indicating that the setting value is being updated and a setting value being updated are displayed on the first to fourth notification display devices 201 to 204. The setting update display flag is a flag that is set to "1" when the setting value update process (FIG. 247) is started and is cleared to "0" when the setting value update process (FIG. 247) is ended. In a situation where the set value update process (FIG. 247) is not executed, basically, the state where the setting update display flag is set to “1” does not become set. However, when the supply of the operating power to the main CPU 63 is stopped in the situation where the set value updating process (FIG. 247) is being executed, and then the supply of the operating power to the main CPU 63 is started. In, the setting update display flag is set to "1". The state in which the setting update display flag is set to "1" is maintained until the process of clearing the setting update display flag to "0" is executed in the setting value update process (FIG. 247).

When a negative determination is made in step SF508 because "1" is not set in the setting update display flag, it is determined whether the reset button 68c is pressed (step SF509). That is, it is determined whether or not the power of the pachinko machine 10 is turned on while the reset button 68c is being pressed and the supply of operating power to the main CPU 63 is started. Here, in the present embodiment, as in the 35th embodiment, the main control device 60 is provided with the setting key insertion portion 68a and the reset button 68c, but is not provided with the update button 68b.

When the reset button 68c has not been pressed (step SF509: NO), it is determined whether the game stop flag in the specific control work area 221 is set to "1" (step SF510). The game stop flag is a flag that is set to "1" when "1" is not set in the power failure flag, when the checksums do not match, or when the set value is abnormal. When the game stop flag is set to "1", the processes of steps S8901 to S8905 are executed in the first timer interrupt process (FIG. 133), while the positive determination is made in step S8906 to steps S8907 to step. The process of S8920 is not executed. As a result, when the power failure flag is not set to “1” because the power failure process was not properly performed at the previous power shutdown, the work area 221 for the specific control and the stack area 222 for the specific control are If at least one of the checksums does not match due to the change in the information storage state since the last power-off, or if the set value is abnormal, power failure monitoring, updating of various counters and illegal operation While the processing for monitoring is executed, the processing for advancing the game is not executed. When an affirmative determination is made in step SF510, the processes of step SF522 and step SF523 described below are executed.

When a negative determination is made in step SF510, it is determined whether or not the setting key inserting section 68a is turned on by using the setting key (step SF511). When the setting key insertion unit 68a is turned on by using the setting key (step SF511: YES), the setting confirmation process is executed (step SF513). Even when the setting key insertion unit 68a is not turned on by using the setting key (step SF511: NO), the setting confirmation display flag provided in the work area 221 for specific control is set to "1". If is set (step SF512: YES), the setting confirmation process is executed (step SF513).

The setting confirmation display flag is a flag for the main CPU 63 to specify that the setting confirmation process (FIG. 246) is being executed, as in the 35th embodiment, and the setting confirmation display flag is "1". When is set, a display indicating that the setting value is being confirmed and a display indicating the currently set setting value are displayed on the first to fourth notification display devices 201 to 204. Be seen. The setting confirmation display flag is a flag that is set to “1” when the setting confirmation process (FIG. 246) is started and is cleared to “0” when the setting confirmation process (FIG. 246) is ended. In the situation where the setting confirmation processing (FIG. 246) is not executed, basically, the setting confirmation display flag is not set to "1". However, when the supply of operating power to the main CPU 63 is stopped in the situation where the setting confirmation process (FIG. 246) is being executed, and then the supply of operating power to the main CPU 63 is started. In the state, the setting confirmation display flag is set to "1". When the setting confirmation display flag is set to "1", the RAM clearing process (FIG. 250) described later is executed, or the setting confirmation display flag is cleared to "0" in the setting confirmation process (FIG. 246). It is maintained until the process is executed.

Not only when the reset button 68c is not pressed as described above and the setting key insertion portion 68a is turned on (that is, when the "setting confirmation operation" is performed), the reset button 68c is The setting confirmation process (FIG. 246) is executed by executing the setting confirmation process (FIG. 246) even when the setting confirmation display flag is set to “1” even when the pressing operation is not performed. When the power failure process is executed under the above condition, the setting confirmation process (FIG. 246) is executed even if the “setting confirmation operation” is not performed when the supply of the operating power is resumed thereafter. As a result, it becomes possible to continuously confirm the current set value of the pachinko machine 10. On the other hand, even when the process for power failure is executed in the situation where the setting confirmation process (FIG. 246) is being executed, if the reset button 68c is pressed when restarting the supply of the operating power after that, Without performing the setting confirmation process (FIG. 246), the RAM clear process (FIG. 250) and the set value update process (FIG. 247) corresponding to the operation performed when the supply of the operating power is restarted are executed. It This makes it possible to prioritize the execution of the RAM clearing process (FIG. 250) or the setting value updating process (FIG. 247) over the setting confirmation process (FIG. 246).

Here, the setting confirmation process executed in step SF513 will be described. FIG. 246 is a flowchart showing the setting confirmation processing. Note that the processing of step SF601 to step SF607 in the setting confirmation processing is executed by using the specific control program and specific control data in the main CPU 63.

First, interrupt permission is set (step SF601). As a result, the first timer interrupt process (FIG. 133) is interrupted and activated in the first interrupt cycle, and the second timer interrupt process (FIG. 134) is interrupted and activated in the second interrupt period.

In the present embodiment, the processing at the start of supply of operating power (steps SF501 to SF523) basically prohibits the interrupts of the first timer interrupt processing (FIG. 133) and the second timer interrupt processing (FIG. 134). In the setting confirmation processing (FIG. 246) and the setting value update processing (FIG. 247), interruption is permitted. Therefore, in the situation where the setting confirmation process (FIG. 246) and the set value update process (FIG. 247) are not executed in the process (steps SF501 to SF523) at the start of supplying the operating power, the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134) are prohibited, and the first timer interrupt process (FIG. 133) is executed in the situation where the process for setting confirmation (FIG. 246) or the process for updating the set value (FIG. 247) is being executed. ) And the execution of the second timer interrupt process (FIG. 134) are permitted. However, in the situation where the setting confirmation process (FIG. 246) or the set value update process (FIG. 247) is being executed, since the start-up processing flag is set to “1”, the first timer interrupt process (FIG. Even if 133) is activated, among the various processes of the first timer interrupt process (FIG. 133), the processes for performing power failure monitoring, updating various counters, and fraudulent monitoring are executed, while progressing the game. The first timer interrupt process (FIG. 133) is terminated without executing the process.

After that, "1" is set to the setting confirmation display flag on condition that "1" is not set to the setting confirmation display flag provided in the work area 221 for specific control (step SF602). When the setting confirmation display flag is set to "1", an affirmative determination is made in step S9005 of the second timer interrupt processing (FIG. 134). (Step S9006) is executed. The processing contents of the setting processing for the fifth display data buffer 275 during the setting confirmation are the same as those in the 45th embodiment. As a result of the processing being performed, a display indicating that the setting value of the pachinko machine 10 is being confirmed and the current setting value of the pachinko machine 10, as shown in the explanatory view of FIG. Is displayed on the first to fourth notification display devices 201 to 204.

After that, the confirmation start command is transmitted to the sound-light side MPU 352 (step SF603). Upon receiving the confirmation start command, the sound-light side CPU 353 can recognize the image indicating that the setting confirmation process (FIG. 246) is being executed and the operation content for ending the setting confirmation process (FIG. 246). The display control device 82 is controlled so that the image to be displayed is displayed on the symbol display device 41. This allows the manager of the gaming hall to recognize that the current setting value of the pachinko machine 10 is being confirmed, and is necessary for ending the setting confirmation process (FIG. 246). It is possible for the manager of the game hall to recognize various operation contents. In addition to or instead of the above-mentioned notification being performed by the symbol display device 41, at least one of the display light emitting unit 53 and the speaker unit 54 may be configured. Further, it may be configured such that external output indicating that the setting confirmation process (FIG. 246) is being executed is performed to a device outside the pachinko machine 10, such as a game hall management computer.

After that, the setting key insertion unit 68a determines whether or not the ON state is switched to the OFF state by using the setting key (step SF604). Specifically, similarly to the setting confirmation process (FIG. 155) in the forty-fifth embodiment, the reception state of the signal received from the detection sensor that detects the state of the setting key insertion portion 68a corresponds to the ON state. It is determined whether the reception state corresponding to the OFF state has been changed to the reception state corresponding to the OFF state. Therefore, not only when the setting key inserting section 68a is maintained in the ON state, but also when the setting confirmation processing (FIG. 246) is started in the situation where the setting key inserting section 68a is in the OFF state, the OFF state is changed. Even if it is maintained, a negative determination is made in step SF604. When it is not specified that the setting key insertion unit 68a has switched from the ON state to the OFF state (step SF604: NO), the process of step SF604 is repeated.

When it is specified that the setting key insertion unit 68a has switched from the ON state to the OFF state (step SF604: YES), the setting confirmation display flag in the specific control work area 221 is cleared to "0" (step SF605). As a result, a negative determination is made in step S9005 of the second timer interrupt processing (FIG. 134), so that the setting processing (step S9006) for the fifth display data buffer 275 during the setting confirmation is not executed. Therefore, on the first to fourth notification display devices 201 to 204, a display indicating that the current setting value of the pachinko machine 10 is being confirmed and a display indicating the current setting value of the pachinko machine 10 are displayed. The state to be performed is released.

After that, the interruption is prohibited (step SF606). As a result, in the case of ending the setting confirmation process (FIG. 246) and returning to the process (step SF501 to step SF523) at the start of supply of operating power in the main process (FIG. 245), the first timer interrupt process (FIG. 133) and the interrupt of the second timer interrupt processing (FIG. 134) are prohibited.

After that, a return command for confirmation is transmitted to the sound-light side MPU 352 (step SF607). By receiving the return command at the time of confirmation, the sound-light side CPU 353 specifies that the processing at the start of supplying the operating power (step SF501 to step SF523) has ended in the main CPU 63, and at the same time, supplies the operating power this time. It is specified that the setting confirmation processing (FIG. 246) has been executed in the processing at the start (steps SF501 to SF523). Then, the processing corresponding to the reception of the confirmation return command is executed. The contents of the processing will be described later.

As described above, when the power of the pachinko machine 10 is turned on while the setting key insertion portion 68a is turned on by the setting key without pressing the reset button 68c, the supply of operating power to the main CPU 63 is started. In the situation where the main process (FIG. 245) has been started and the reset button 68c has not been pressed and the setting key insertion portion 68a has been turned ON, the main process (FIG. 245) advances the game. The setting confirmation process (FIG. 246) is executed in a condition before the process is executed, which is a process at the start of supplying the operating power. As a result, it becomes possible to confirm the set value in a situation where the game is not being played.

Returning to the description of the main processing (FIG. 245), when the setting key insertion unit 68a has not been turned on using the setting key and the setting confirmation display flag is not set to "1" (step SF511 and (Step SF512: NO), the normal recovery command is transmitted to the sound/light side MPU 352 (step SF514). By receiving the normal return command, the sound-light side CPU 353 specifies that the processing (steps SF501 to SF523) at the time of starting the supply of the operating power is completed in the main CPU 63, and at the time of starting the supply of the operating power this time. It is specified that the RAM clear process (FIG. 250), the setting confirmation process (FIG. 246), and the set value update process (FIG. 247) are not executed in the process (step SF501 to step SF523). Then, the processing corresponding to the reception of the normal return command is executed. The contents of the processing will be described later.

On the other hand, when it is determined that the reset button 68c has been pressed, and it is determined that the setting key insertion unit 68a has been turned ON using the setting key (step SF509 and step SF515: YES), Alternatively, when it is determined in step SF508 that the setting update display flag is set to "1", the setting value update processing is executed (step SF516). Not only when the reset button 68c is pressed and the setting key insertion portion 68a is turned ON (that is, when the "setting change operation" is performed) as described above, the reset button 68c Setting value update processing (FIG. 247) is executed even when the setting update display flag is set to "1" regardless of whether or not the pressing operation and the ON operation of the setting key insertion portion 68a are performed, thereby updating the setting value. When the process at the time of power failure is executed in the situation where the process (FIG. 247) is being executed, the operation content at the time of starting the supply of the operating power thereafter is “no operation”, “RAM clear operation”, “setting change”. Regardless of whether it is an “operation” or a “setting confirmation operation”, the setting value update processing (FIG. 247) is executed. As a result, it becomes possible to give priority to the execution of the setting value update processing (FIG. 247).

Here, the setting value update processing executed in step SF516 will be described. FIG. 247 is a flowchart showing the setting value update processing. Note that the processing of steps SF701 to SF714 in the setting value update processing is executed using the program for specific control and the data for specific control in the main CPU 63.

First, interrupt permission is set (step SF701). As a result, the first timer interrupt process (FIG. 133) is interrupted and activated in the first interrupt cycle, and the second timer interrupt process (FIG. 134) is interrupted and activated in the second interrupt period.

In the present embodiment, the processing at the start of supply of operating power (steps SF501 to SF523) basically prohibits the interrupts of the first timer interrupt processing (FIG. 133) and the second timer interrupt processing (FIG. 134). In the setting confirmation processing (FIG. 246) and the setting value update processing (FIG. 247), interruption is permitted. Therefore, in the situation where the setting confirmation process (FIG. 246) and the set value update process (FIG. 247) are not executed in the process (steps SF501 to SF523) at the start of supplying the operating power, the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134) are prohibited, and the first timer interrupt process (FIG. 133) is executed in the situation where the process for setting confirmation (FIG. 246) or the process for updating the set value (FIG. 247) is being executed. ) And the execution of the second timer interrupt process (FIG. 134) are permitted. However, in the situation where the setting confirmation process (FIG. 246) or the set value update process (FIG. 247) is being executed, since the start-up processing flag is set to “1”, the first timer interrupt process (FIG. Even if 133) is activated, among the various processes of the first timer interrupt process (FIG. 133), the processes for performing power failure monitoring, updating various counters, and fraudulent monitoring are executed, while progressing the game. The first timer interrupt process (FIG. 133) is terminated without executing the process.

After that, "1" is set to the setting update display flag on condition that "1" is not set to the setting update display flag provided in the work area 221 for specific control (step SF702). When the setting update display flag is set to "1", a positive determination is made in step S9003 of the second timer interrupt process (FIG. 134), and the setting process for the fifth display data buffer 275 during the setting update is performed. (Step S9004) is executed. The processing content of the setting processing for the fifth display data buffer 275 during the setting update is the same as that in the 45th embodiment. By executing the process, as shown in the explanatory view of FIG. 124(a), for example, a display indicating that the setting value of the pachinko machine 10 is being updated and selection as an update target of the pachinko machine 10 are made. The displayed set values are displayed on the first to fourth notification display devices 201 to 204.

After that, initial setting at the start is performed (step SF703). In the initial setting, the game stop flag provided in the work area 221 for specific control is cleared to "0". As for the game stop flag, when the power failure flag is not set to "1" because the power failure process was not properly performed at the previous power shutdown (step SF504: NO), the work area 221 for specific control and If the checksums do not match due to the change in the storage state of information since the last power-off of at least one of the stack areas 222 for specific control (step SF506: NO), or the setting reference area 341 This is a flag that is set to "1" in step SF520 of the main process (FIG. 245) when the set value corresponding to the information stored in is not in the normal range (step SF507: NO). When the game stop flag is set to "1", the processes of steps S8901 to S8905 are executed in the first timer interrupt process (FIG. 133), while the positive determination is made in step S8906 to steps S8907 to step. The process of S8920 is not executed. As a result, when the information abnormality of the main RAM 65 as described above occurs, the processing for performing the power failure monitoring, the updating of various counters and the illegality monitoring is executed, while the processing for advancing the game is executed. Will not be done. By clearing the game stop flag to "0" in the process of step SF703, the state in which the occurrence of the information abnormality of the main RAM 65 is specified is canceled when the set value update process (FIG. 247) is executed. Is possible.

After that, "1" is set in the setting update area 342 (see FIG. 154) in the specific control work area 221 (step SF704). The setting update area 342 is a storage area for storing information on the setting value being updated in the setting value updating process (FIG. 247) as in the 45th embodiment. When the numerical information of “1” is stored in the setting update area 342, the set value of the update target (selection target or change target) is “setting 1”. When the numerical information of “2” is stored in the setting update area 342, the setting value to be updated is “setting 2”. When the numerical information of “3” is stored in the setting update area 342, the setting value to be updated is “setting 3”. When the numerical information of "4" is stored in the setting update area 342, the setting value to be updated is "setting 4". When the numerical information of "5" is stored in the setting update area 342, the setting value to be updated is "setting 5". When the numerical information of “6” is stored in the setting update area 342, the setting value to be updated is “setting 6”.

By setting "1" in the setting update area 342 in step SF704, the setting value to be updated becomes "setting 1". That is, in the present embodiment, the setting value to be updated is “setting 1” when the setting value update process (FIG. 247) is started, whichever setting value the pachinko machine 10 currently has.

After that, the update start command is transmitted to the sound-light side MPU 352 (step SF705). By receiving the update start command, the sound-light side CPU 353 receives an image, which shows that the setting value update processing (FIG. 247) is being executed, an image for making it possible to recognize the operation content for changing the setting value, And the display control device 82 is display-controlled so that the image for making the operation contents for recognizing the setting value update processing (FIG. 247) recognizable is displayed on the symbol display device 41. This allows the manager of the game hall to recognize that the setting value is being changed, and the operation content and the setting value update processing necessary to change the setting value (FIG. 247). It becomes possible for the manager of the game hall to recognize the operation content necessary for ending the game. In addition to or instead of the above-mentioned notification being performed by the symbol display device 41, at least one of the display light emitting unit 53 and the speaker unit 54 may be configured. In addition, a configuration may be adopted in which an external output indicating that the set value update processing (FIG. 247) is being executed is performed to a device outside the pachinko machine 10, such as a game hall management computer.

After that, it is determined whether or not the setting value information stored in the setting update area 342 is any one of "1" to "6" (step SF706). If it is not any of "1" to "6" (step SF706: NO), "1" is set in the setting update area 342 (step SF707). As a result, the setting value to be updated becomes “setting 1”.

When an affirmative determination is made in step SF706 or the processing of step SF707 is executed, it is determined whether or not the setting key insertion unit 68a has switched from the ON state to the OFF state using the setting key (step SF708). Specifically, it is determined whether the reception state of the signal received from the detection sensor that detects the state of the setting key insertion unit 68a has changed from the reception state corresponding to the ON state to the reception state corresponding to the OFF state. To do. Therefore, the OFF state is maintained not only when the setting key inserting section 68a is maintained in the ON state, but also when the setting value updating process is started in the situation where the setting key inserting section 68a is in the OFF state. Also in this case, a negative determination is made in step SF708.

When a negative determination is made in step SF708, the value of the setting update area 342 is incremented by 1 on the condition that the reset button 68c is pressed (step SF709: YES) (step SF710). As a result, each time the reset button 68c is pressed once, the setting value is updated by one step. Further, when the reset button 68c is not pressed (step SF709: NO) or when the value of the setting update area 342 is incremented by 1, the process returns to step SF706, but the setting update is performed in step SF706. If it is determined that the value of the use area 342 is 7 or more, "1" is set in the setting update area 342 in step SF707. As a result, when the reset button 68c is pressed once in the situation of "setting 6", the process returns to "setting 1".

When it is specified that the setting key insertion unit 68a is switched from the ON state to the OFF state (step SF708: YES), the setting reference area 341 is overwritten with the setting value information stored in the setting update area 342 ( Step SF711). As a result, the setting value information obtained as a result of the update in the setting value updating process this time (FIG. 247) is set in the setting reference area 341, and the setting value corresponding to the set information is the current value. It becomes the set value of the pachinko machine 10.

After that, the interruption is prohibited (step SF712). As a result, when the setting value update process (FIG. 247) is terminated and the process returns to the process (step SF501 to step SF523) at the start of supply of operating power in the main process (FIG. 245), the first timer interrupt process (FIG. 133) and the interrupt of the second timer interrupt processing (FIG. 134) are prohibited.

After that, the RAM clear processing is executed (step SF713). In the RAM clearing process, similarly to the RAM clearing process (step SA416) in the forty-fifth embodiment, in the work area 221 for specific control, the area where the setting value information indicating the setting state of the pachinko machine 10 is set (that is, Except for the setting reference area 341), the work area 221 for the specific control is cleared to "0" and the initial setting is executed. As a result, the area indicating whether or not the winning/winning lottery mode is the high-probability mode is cleared to "0". The mode is a low probability mode. In addition, the game times are not being executed, the opening/closing execution mode is not being executed, and the general-purpose display unit 38a is not being variably displayed, and the general electric accessory 34a is in the closed state. It becomes a situation. Further, since the hold storage area 65a and the universal electric power reserve area 65c provided in the work area 221 for specific control are also cleared to "0", the reserved information for the special figure display section 37a is deleted and the general figure display section is deleted. The hold information for 38a is deleted. Further, the setting update display flag and the setting confirmation display flag provided in the specific control work area 221 are cleared to "0". In addition, the setting update area 342 provided in the specific control work area 221 is cleared to “0”. Further, the game stop flag provided in the work area 221 for specific control is cleared to "0". In the RAM clearing process, the stack area 222 for specific control is cleared to "0" and the initial setting is executed. In the RAM clearing process, various registers of the main CPU 63 are cleared to "0" and then the initial setting is executed. In this initial setting, the same processing as the internal function register setting processing in step SF502 is executed. The process for clearing “0” and the process for initial setting are not executed for the work area 223 for non-specific control and the stack area 224 for non-specific control.

After that, a return command for updating is transmitted to the sound-light side MPU 352 (step SF714). By receiving the return command at the time of update, the sound-light side CPU 353 specifies that the process at the time of starting the supply of the operating power (step SF501 to step SF523) is completed in the main CPU 63, and supplies the operating power at this time. It is specified that the setting value update processing (FIG. 247) has been executed in the processing at the start (step SF501 to step SF523). Then, the processing corresponding to the reception of the update return command is executed. The contents of the processing will be described later.

Based on not only performing the power ON operation of the pachinko machine 10 while pressing the reset button 68c as described above, but also performing the power ON operation of the pachinko machine 10 while further operating the setting key insertion portion 68a by the setting key. The set value update process (FIG. 247) is executed. Further, as described above, the setting confirmation processing (FIG. 246) is performed based on the power-on operation of the pachinko machine 10 while the setting key insertion portion 68a is turned on by the setting key without pressing the reset button 68c. Executed. As a result, it becomes possible to make the ON operation for the setting key insertion unit 68a common as the operation for executing the setting related processing regarding the setting value. Therefore, it becomes possible for the manager of the game hall to easily understand the operation content for generating the setting-related processing.

Further, when the power of the pachinko machine 10 is turned on while the setting key insertion portion 68a is turned on by the setting key, and the pressing operation of the reset button 68c is not added, the setting confirmation process (FIG. 246) is performed. When the reset button 68c is pressed, the set value updating process (FIG. 247) is executed. As a result, it becomes possible to make the target process of the setting confirmation process (FIG. 246) and the setting value update process (FIG. 247) different depending on whether the reset button 68c is pressed. Therefore, it becomes possible for the manager of the game hall to easily understand the operation content for executing the desired processing of the setting confirmation processing (FIG. 246) and the setting value update processing (FIG. 247). In addition, by making the operation contents for executing the setting value update processing (FIG. 247) larger than the setting confirmation processing (FIG. 246), the action for making the setting value update processing (FIG. 247) illegal is performed. It is possible to make it difficult.

Returning to the explanation of the main processing (FIG. 245), when it is determined in step SF509 that the reset button 68c has been pressed, and the setting key insertion portion 68a has not been turned on using the setting key. If determined (step SF515: NO), it is determined whether or not "1" is set to the game stop flag in the work area 221 for specific control (step SF517). The game stop flag is a flag that is set to "1" when "1" is not set in the power failure flag, when the checksums do not match, or when the set value is abnormal. When the game stop flag is set to "1", the processes of steps S8901 to S8905 are executed in the first timer interrupt process (FIG. 133), while the positive determination is made in step S8906 to steps S8907 to step. The process of S8920 is not executed. As a result, when the power failure flag is not set to “1” because the power failure process was not properly performed at the previous power shutdown, the work area 221 for the specific control and the stack area 222 for the specific control are If at least one of the checksums does not match due to the change in the information storage state since the last power-off, or if the set value is abnormal, power failure monitoring, updating of various counters and illegal operation While the processing for monitoring is executed, the processing for advancing the game is not executed.

When "1" is not set in the game stop flag (step SF517: NO), RAM clear processing is executed (step SF518). The contents of the RAM clearing process are the same as the contents of the RAM clearing process of step SF713 in the set value updating process (FIG. 247).

Then, the return command at the time of clear is transmitted to the sound-light side MPU 352 (step SF519). By receiving the return command at the time of clearing, the sound-light side CPU 353 identifies that the process (step SF501 to step SF523) at the time of starting the supply of the operating power is completed in the main CPU 63, and supplies the operating power this time. It is specified that the RAM clear process (step SF518) has been executed in the situation where the setting value update process (FIG. 247) has not been executed in the process at the start (steps SF501 to SF523). Then, the processing corresponding to the reception of the clear return command is executed. The contents of the processing will be described later.

In the main processing (FIG. 245), when a negative determination is made in any of step SF504, step SF506 and step SF507, that is, when the power failure flag is not set to "1", the checksums do not match, or the setting is made. If the value is abnormal, the game stop flag in the work area 221 for specific control is set to "1" (step SF520). As described above, by setting the game stop flag to "1", the processes of steps S8901 to S8905 are executed in the first timer interrupt process (FIG. 133), while the positive determination is made in step S8906. The processes of steps S8907 to S8920 are not executed. As a result, when the power failure flag is not set to “1” because the power failure process was not properly performed at the previous power shutdown, the work area 221 for the specific control and the stack area 222 for the specific control are If at least one of the checksums does not match due to the change in the information storage state since the last power-off, or if the set value is abnormal, power failure monitoring, updating of various counters and illegal operation While the processing for monitoring is executed, the processing for advancing the game is not executed.

Then, it is determined whether or not the reset button 68c has been pressed (step SF521). If the reset button 68c has not been pressed (step SF521: NO), an abnormal command indicating that an abnormality has occurred with respect to the power failure flag, the checksum, or the set value at the start of supplying the operating power is transmitted to the sound-light side MPU 352. (Step SF522). Upon receiving the abnormality command, the sound-light side CPU 353 causes the display light emitting unit 53 to emit light in a manner corresponding to the information abnormality at the time of starting the supply of the operating power, and the speaker unit 54 "Please change the setting." Is output. Moreover, the character image "Please change the setting." is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are ended when the supply of operating power to the pachinko machine 10 is stopped. However, even if the supply of the operating power to the pachinko machine 10 is temporarily stopped, the above notification is given when the supply of the operating power to the pachinko machine 10 is restarted until the setting value update processing (FIG. 247) is executed. It will be started again.

After that, external output processing at the time of abnormality is executed (step SF523). In the external output process at the time of abnormality, a process for externally outputting an abnormality signal to the management computer of the game hall is executed. In this case, the signal output of the abnormal signal is performed over a predetermined period (for example, 100 milliseconds). However, the present invention is not limited to this, and under the condition that the game stop flag is set to "1", the signal output of the abnormal signal is continued, and the game stop flag is cleared to "0", thereby indicating the abnormal signal. The signal output may be stopped. The abnormality signal can also be output when an abnormality different from the abnormality regarding the power failure flag, the checksum, and the set value occurs. For example, in the fraud detection process (step S8905) of the first timer interrupt process (FIG. 133), even when it is specified that a fraud of the monitoring target (illegal radio wave detection or fraudulent magnetism detection) occurs, the abnormal signal is generated It is output externally. However, the configuration is not limited to such a configuration in which an abnormality signal is also used, and a configuration in which an abnormality signal dedicated to an abnormality related to a power failure flag, checksum, or set value may be externally output may be used. It is also possible to have a configuration in which an abnormality signal corresponding to each of the abnormality regarding the check, the abnormality regarding the checksum, and the abnormality regarding the set value is externally output.

When the reset button 68c has been pressed (step SF521: YES), it is determined whether or not the setting key inserting section 68a has been turned ON using the setting key (step SF515). When the reset button 68c is pressed and the setting key inserting section 68a is turned on by using the setting key (step SF515 and step SF521: YES), the set value updating process is executed (step SF516). The processing content of the setting value update processing is as already described. That is, when the operating power is supplied to the main CPU 63 in the situation where the “setting change operation” is being performed, one of step SF504, step SF506, and step SF507 due to the occurrence of an abnormality in the main RAM 65. Even if a negative determination is made in step S1, the setting value update processing (FIG. 247) is executed. Thereby, it becomes possible to give priority to the change of the set value. Further, in the set value update processing (FIG. 247), the game stop flag is cleared to “0” by executing the initial setting at the start in step SF703 as already described. As a result, when the set value update process (FIG. 247) is executed, it is possible to eliminate the state in which an abnormality has occurred in the main RAM 65 after the set value update is completed.

On the other hand, when the reset button 68c is pressed but the setting key insertion portion 68a is not turned on (step SF521: YES, step SF515: NO), the game stop flag in the work area 221 for specific control is set to "1". Is set (step SF517). In the process of step SF517 after the game stop flag is set to "1" in step SF520, the game stop flag is set to "1" as a matter of course, so an affirmative determination is made in step SF517. In this case, an abnormal command is transmitted to the sound/light side MPU 352 in step SF522, and an abnormal signal is externally output in step SF523.

That is, when an abnormality related to the power failure flag, the checksum, and the set value occurs and a negative determination is made in any of step SF504, step SF506, and step SF507, the main CPU 63 in the situation where the “RAM clear operation” is performed. The RAM clearing process (step SF518) is not executed even if the supply of operating power to the device is started. Also, when the game stop flag is set to "1" and the "RAM clear operation" is being performed and the supply of operating power to the main CPU 63 is started, the RAM clear process ( Step SF518) is not executed. As a result, even if the supply of operating power to the main CPU 63 is started while the "RAM clear operation" is being performed, the state in which the game stop flag is set to "1" can be prevented from being resolved. It will be possible. On the other hand, when the "setting change operation" is performed, the setting value update processing (FIG. 247) is executed and the setting is performed regardless of whether or not the game stop flag is set to "1". The game stop flag is cleared to "0" in the initial setting (step SF703) at the start of the value updating process (Fig. 247). As a result, it becomes necessary to execute the set value updating process (FIG. 247) in order to cancel the state in which the game stop flag is set to "1". Therefore, when the information abnormality of the work area 221 for specific control occurs, not only the process for initializing the work area 221 for specific control, but also the resetting of the set value can be required. ..

Further, when the supply of operating power to the main CPU 63 is started in a situation where the game stop flag is set to "1", when "setting change operation" is not performed, that is, "no operation" In the case of, or when the “RAM clear operation” or the “setting confirmation operation” is performed, an affirmative determination is made in step SF510 or step SF517, so that an abnormal command is transmitted in step SF522 and an abnormality is detected in step SF523. The external output processing of is executed. As a result, when the game stop flag is set to "1", the set value update processing (FIG. 247) is executed regardless of the processing results of step SF504, step SF506 and step SF507 in the subsequent main processing. Every time the supply of operating power to the main CPU 63 is started, an abnormality notification in the pachinko machine 10 and an external output at the time of an abnormality to the outside of the pachinko machine 10 are performed. Therefore, it becomes possible to let the manager of the game hall recognize that the set value should be changed.

When the process of step SF513 is executed, the process of step SF514 is executed, the process of step SF516 is executed, the process of step SF519 is executed, or the process of step SF523 is executed, the specific control Information corresponding to the initial check period (specifically, 5 seconds) is set in the checking counter provided in the work area 221 (step SF524). The value set in the checking counter is decremented by 1 each time the second timer interrupt process (FIG. 134) is activated, as in the 35th embodiment. If a value greater than or equal to 1 is set in the checking counter, the process of step S9102 is executed in the normal setting process (FIG. 135) in the second timer interrupt process (FIG. 134), so that Similar to the above embodiment, the check display is continued on the first to fourth notification display devices 201 to 204.

According to the above configuration, when the supply of the operating power to the main CPU 63 is started, the residual processing is performed after the processing at the start of the supply of the operating power (steps SF501 to SF523) is completed in the main CPU 63. Before (Steps SF526 to SF529) are started, the initial check period is started. Accordingly, since it is not necessary to control the initial check period in a situation where the process at the start of supplying the operating power (steps SF501 to SF523) is executed, the process at the start of supplying the operating power (steps SF501 to step SF501). It is possible to reduce the processing load in the situation where SF523) is being executed.

Further, the setting confirmation process (FIG. 246) and the set value update process (FIG. 247) are executed as the process at the start of the supply of the operating power (steps SF501 to SF523), while the initial check period is the operating power. Is started after the processing (step SF501 to step SF523) at the start of supply of No. is completed. Accordingly, even if the check display is performed on the first to fourth notification display devices 201 to 204 during the initial check period, the set values are displayed using the first to fourth notification display devices 201 to 204. It becomes possible not to affect.

After that, the start-up processing flag in the work area 221 for specific control is cleared to "0" (step SF525). When the first timer interrupt process (FIG. 133) is started by clearing the start-up processing flag “0”, a negative determination is made in step S8906, and thus not only the processes of steps S8901 to S8905 The processing of steps S8907 to S8920 will be executed, and the state where the processing for advancing the game is not executed is released. In step SF525, the power failure flag in the specific control work area 221 is also cleared to "0".

After that, the process proceeds to the residual processing of steps SF526 to SF529. In other words, the main CPU 63 is configured to periodically execute the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134), but between the one timer interrupt process and the next timer interrupt process. There will be some residual time. This remaining time will vary depending on the processing completion time of each timer interrupt processing, but the remaining processing of steps SF526 to SF529 is repeatedly executed by utilizing this irregular time. In this respect, it can be said that the residual process of steps SF526 to SF529 is an irregular process that is irregularly executed. In steps SF526 to SF529, the same processes as steps S113 to S116 of the main process (FIG. 9) in the first embodiment are executed.

Next, the setting mode of each area in the main RAM 65 will be described with reference to the explanatory diagram of FIG. 248.

Similar to the fifteenth embodiment, the main RAM 65 is provided with a work area 221, a stack area 222 for specific control, a work area 223 for non-specific control, and a stack area 224 for non-specific control. Has been. In the main RAM 65, the address range of the work area 221 for specific control, the address range of the stack area 222 for specific control, the address range of the work area 223 for non-specific control, and the stack area for non-specific control The 224 address range is clearly distinguished.

The address range of each of the areas 221 to 224 will be described in detail. The address of the main side RAM 65 is set as 2-byte data. For convenience of explanation, 2-byte address data will be described as 4-digit hexadecimal data. The area of each continuous address within the range of “0000” to Y(k−1), which is the start address of the 2-byte data, is an unused address, and is followed by the address Y(k )-"00FF", the area of each continuous address is set as the work area 221 for specific control. Further, the addresses "0100" to Y(l-1) consecutive to the addresses Y(k) to "00FF" are addresses of unused areas, and the addresses Y(l) to "01FF" follow thereafter. The area of each continuous address within the range is set as a stack area 222 for specific control. Further, the addresses "0200" to Y(m-1) consecutive to the addresses Y(l) to "01FF" are addresses of the unused areas, and the addresses Y(m) to "02FF" follow thereafter. The area of each continuous address within the range is set as the work area 223 for non-specific control. Further, the addresses "0300" to Y(n-1) consecutive to the addresses Y(m) to "02FF" are addresses of unused areas, and the addresses Y(n) to "03FF" follow thereafter. The area of each successive address within the range is set as a stack area 224 for non-specific control.

The relationship between each area and the address as described above is set in both the physical address in the main RAM 65 and the logical address on the memory map recognized by the main CPU 63. Further, the address range (Y(k) to “00FF”) of the work area 221 for specific control, the address range (Y(l) to “01FF”) of the stack area 222 for specific control, and the non-specific control Of the work area 223 (Y(m) to “02FF”) and the address range of the stack area 224 for non-specific control (Y(n) to “03FF”) are different from each other. Specifically, the address range (Y(k) to “00FF”) of the work area 221 for specific control is the widest, and the address range (Y(m) to “02FF” of the work area 223 for non-specific control is next. )) is wide, then the address range of the stack area 222 for specific control (Y(l) to “01FF”) is wide, and the address range of the stack area 224 for non-specific control (Y(n) to “03FF”). ) Is the narrowest. However, the present invention is not limited to this, and the widths of the address ranges of the areas 221 to 224 may be the same or substantially the same.

When the work area 221 for specific control and the work area 223 for non-specific control are set separately as described above, the main CPU 63 executes the specific control and the non-specific control is executed. Thus, different areas of the main RAM 65 are used when various calculations are executed. As a result, when one of the specific control and the non-specific control is executed, it is possible to make it difficult for an event such that the information in the main RAM 65 necessary for the other is erased. Incidentally, when writing information to each work area 221, 223 and reading information from each work area 221, 223, the main CPU 63 issues a load instruction.

Since the stack area 222 for the specific control and the stack area 224 for the non-specific control are separately set, the main CPU 63 can perform the specific control and the non-specific control by the main CPU 63. Different areas of the main RAM 65 are used when the information stored in the register of the side CPU 63 is saved and when the information of the return address on the program is stored. As a result, in the case where one of the specific control and the non-specific control is being executed, the information stored in the register of the main CPU 63 is saved and the information of the return address on the program is stored. It is possible to make it difficult for an event such as the deletion of the stored information to occur. Incidentally, when writing information to the stack areas 222 and 224, a push command is issued by the main CPU 63, and when reading information from the stack areas 222 and 224, a pop instruction is issued by the main CPU 63. Further, when reading information from the stack areas 222 and 224, the order of writing to the stack areas 222 and 224 is to be read first after the later information.

When the main CPU 63 executes a process corresponding to the specific control, the main CPU 63 can write information to the specific control work area 221 and the specific control stack area 222, and at the same time, can execute the specific control. It is possible to read information from the work area 221 and the stack area 222 for specific control. On the other hand, when the main CPU 63 executes a process corresponding to the specific control, the main CPU 63 can read information from the non-specific control work area 223 and the non-specific control stack area 224. Information cannot be written in the work area 223 for non-specific control and the stack area 224 for non-specific control. This makes it possible to prevent the information used in the process corresponding to the non-specific control from being accidentally erased in the situation where the process corresponding to the specific control is being executed.

When the main CPU 63 executes a process corresponding to the non-specific control, the main CPU 63 can write information to the work area 223 for non-specific control and the stack area 224 for non-specific control, and It is possible to read information from the work area 223 for non-specific control and the stack area 224 for non-specific control. On the other hand, when the main CPU 63 executes a process corresponding to the non-specific control, the main CPU 63 can read information from the specific control work area 221 and the specific control stack area 222. It is impossible to write information to the work area 221 for specific control and the stack area 222 for specific control. This makes it possible to prevent the information used in the process corresponding to the specific control from being accidentally deleted in the situation where the process corresponding to the non-specific control is being executed.

The backup power is supplied to the main RAM 65 even after the power supply to the pachinko machine 10 is cut off. The backup power is supplied to the work area 221 for specific control, the stack area 222 for specific control, and the non-specific control. Are supplied to all of the work area 223 for stacking and the stack area 224 for non-specific control. As a result, the information stored in the specific control work area 221, the specific control stack area 222, the non-specific control work area 223, and the non-specific control stack area 224 is turned off by the pachinko machine 10. Even after that, the data is retained while the backup power is being supplied.

Here, the work area 221 for specific control, the stack area 222 for specific control, the work area 223 for non-specific control, and the stack area 224 for non-specific control have lower end addresses if the end addresses are hexadecimal numbers. 2 digits of “FF” are set to be “FF”, and if they are binary numbers, the lower 8 bits (that is, the lower 1 byte) are all set to “1”. On the other hand, if the end address of the specific control work area 221, the specific control stack area 222, the non-specific control work area 223 and the non-specific control stack area 224 is a hexadecimal number, the upper two digits In the case of a binary number, the addresses are different as a whole because the upper 8 bits following the most significant bit (that is, the upper 1 byte) are different. That is, the specific control work area 221, the specific control stack area 222, the non-specific control work area 223, and the non-specific control stack area 224 are all in the lower predetermined range (lower side) of the end address. Address data of 1 byte) is common to the predetermined data.

The main CPU 63 reads data from an area within a predetermined range of the main RAM 65, such as RAM clear processing (FIG. 250), non-specific control clear processing (FIG. 252), and checksum calculation processing (FIG. 253). In the case and when writing data in an area of a predetermined range of the main RAM 65 (hereinafter, reading data and writing data are collectively referred to as specific processing), first, a start address is set as a target address, and an area corresponding to the target address is set. The specific processing is executed for. After that, by adding "1" to the target address, the next address is used as the target address, and the specifying process is executed for the area corresponding to the target address. Then, by adding "1" to the target address, the next address is set as the target address and the specific processing is executed for the area corresponding to the target address until the target address becomes the end address. continue.

The main CPU 63 is provided with an address counter 515 as shown in FIG. FIG. 249A is an explanatory diagram for explaining the contents of the address counter 515. The address counter 515 is a counter for setting address data of the target address. The main CPU 63 sets the address data of the start address in the address counter 515 when starting the specific process, and adds "1" to the address counter 515 when updating the target address. Then, the main CPU 63 grasps the target address by referring to the address counter 515.

The address counter 515 has a data capacity of 2 bytes in response to the address of the main RAM 65 being set as address data of 2 bytes. That is, the address counter 515 includes an upper byte 515a consisting of 1 byte and a lower byte 515b consisting of 1 byte. When the address counter 515 adds "1" to update the target address, "1" is added to the lower byte 515b.

The main CPU 63 is provided with a carry flag 516 as shown in FIG. When the target address becomes the next address by adding "1" to the target address in a situation where the lower-order predetermined range of address data in the target address is the predetermined data, the carry flag 516 is set to "1". Is set. Specifically, if the target address is a hexadecimal number, the lower two digits are “FF”, and if the target address is a binary number, the lower eight bits (that is, the lower byte 515b) are all “1”. If "1" is added to the target address, a carry to the most significant two digits occurs in hexadecimal, and if it is a binary number, the upper eight bits continue from the most significant bit. When a carry to the upper byte 515a occurs, the carry flag 516 is set to "1".

FIGS. 249(b) to 249(e) are explanatory diagrams for explaining how the carry flag 516 is set to "1" as a result of the target address being updated.

First, a case where "1" is not set in the carry flag 516 when the target address is updated will be described. As shown in FIG. 249(b), when the lower byte 515b is not all "1" (that is, the lower byte 515b is not the maximum value), "1" is added to the lower byte 515b to update the target address. As a result, the address data of the lower byte 515b is increased by "1" as shown in FIG. 249(c). In this case, since the lower byte 515b does not become all zeros and no carry to the upper byte 515a occurs, the carry flag 516 is maintained at "0" and the address data of the upper byte 515a is maintained.

Next, a case where "1" is set in carry flag 516 when the target address is updated will be described. As shown in FIG. 249(d), in the situation where the lower byte 515b is all "1" (that is, the lower byte 515b is the maximum value), "1" is added to the lower byte 515b to update the target address. As a result, the lower byte 515b becomes all zeros as shown in FIG. 249(e). In this case, carry flag 516 is set to "1", and main CPU 63 confirms that carry flag 516 is set to "1" to recognize that a carry has occurred to upper byte 515a. Therefore, "1" is added to the upper byte 515a.

That is, if "1" is added to the lower byte 515b and the lower byte 515b becomes all zeros, it is necessary to add "1" to the upper byte 515a, but "1" is added to the upper byte 515a. A carry flag 516 is provided for the main CPU 63 to specify whether or not the addition is required. When the carry flag 516 is not set to "1", "1" is not added to the upper byte 515a, and when the carry flag 516 is set to "1", the higher order byte 515a is not added. "1" is added to the byte 515a.

In such a configuration, as described above, the specific control work area 221, the specific control stack area 222, the non-specific control work area 223, and the non-specific control stack area 224 are all located at the lower side of the end address. The address data in the predetermined range is common to the predetermined data. Specifically, if the end address of each of the specific control work area 221, the specific control stack area 222, the non-specific control work area 223, and the non-specific control stack area 224 is a hexadecimal number. The lower two digits are "FF", and if they are binary numbers, the lower eight bits (that is, the lower byte 515b) are all set to "1". As a result, the specific processing is executed on any of the specific control work area 221, the specific control stack area 222, the non-specific control work area 223, and the non-specific control stack area 224. In the case, in the case where the specific processing is completed for the area corresponding to the end address of the areas 221 to 224 which is the target of executing the specific processing and the target address is updated to the next address, the carry flag “1” is set in 516. Therefore, the main CPU 63 confirms whether or not "1" is set in the carry flag 516, so that the area corresponding to the end address of the areas 221 to 224 for which the specific processing is executed is set. On the other hand, it is possible to specify whether or not the specifying process is executed. Therefore, it is not necessary to perform address comparison processing when determining whether or not the addresses are the end addresses of the areas 221-224, and thus the processing load can be reduced.

The process of setting "1" to the carry flag 516 when the carry occurs is a process of updating the target address by adding "1" to the target address (target address addition process (FIG. 251)). It is executed in. In this case, the target address addition process (FIG. 251) is set as a common subroutine in the specific control program, and the target address addition process is performed regardless of which type of specific process is executed as the specific control. When executing a process, a common subroutine is called and executed. Further, the process of adding the target address is also set in the non-specific control program.

As described above, the specific control work area 221, the specific control stack area 222, the non-specific control work area 223, and the non-specific control stack area 224 all have a lower end if the end address is a hexadecimal number. The two digits are "FF", and if they are binary numbers, the lower 8 bits (that is, lower byte 515b) are set to all "1". The address range is set so that the lower-order side predetermined range of address data becomes the predetermined data. On the other hand, the number of addresses required for each area 221 to 224 is less than 256 in all. Therefore, in the order of addresses, the address range before the work area 221 for specific control, the address range between the work area 221 for specific control and the stack area 222 for specific control, the stack area 222 for specific control, and the like. An unused area exists in each of the address range between the work area 223 for non-specific control and the address area between the work area 223 for non-specific control and the stack area 224 for non-specific control. ing.

Next, the RAM clearing process executed by the main CPU 63 will be described with reference to the flowchart of FIG. The RAM clearing process is executed in step SF518 of the main process (FIG. 245) and also in step SF713 of the set value updating process (FIG. 247). The processes of steps SF801 to SF810 in the RAM clearing process are executed using the specific control program and the specific control data in the main CPU 63.

First, in the work area 221 for specific control, a clear start address, which is a start address when executing the RAM clear process, is set as a target address (step SF801). In this case, the address data corresponding to the current clear start address is set in each of the upper byte 515a and the lower byte 515b in the address counter 515 of the main CPU 63. That is, the upper 8 bits in the present clear start address are set in the upper byte 515a, and the lower 8 bits in the present clear start address are set in the lower byte 515b. A setting reference area 341 is set in an area corresponding to the start address of the specific control work area 221, and a clear start address is set to an address in the next order with respect to the setting reference area 341. .. As a result, the setting reference area 341 can be excluded from the execution targets of the RAM clearing process. In step SF801, carry flag 516 is cleared to "0" and the work completion flag provided in main CPU 63 is cleared to "0". After that, the area corresponding to the target address in the main RAM 65 is cleared to "0" (step SF802). Then, the process of adding the target address is executed (step SF803).

FIG. 251 is a flowchart showing the process of adding the target address. In the process of adding the target address, first, "1" is added to the lower byte 515b of the address counter 515 of the main CPU 63 (step SF901). In this case, when “1” is added to the lower byte 515b in a situation where the 8 bits of the lower byte 515b are all “1”, the 8 bits of the lower byte 515b become all zeros. When all 8 bits of the lower byte 515b are zero (step SF902: YES), the carry flag 516 of the main CPU 63 is set to "1" (step SF903).

If a negative determination is made in step SF902, or if the process of step SF903 is executed, it is determined in step SF904 whether or not "1" is set in the carry flag 516 of the main CPU 63. When carry flag 516 is set to "1" (step SF904: YES), "1" is added to upper byte 515a in address counter 515 of main CPU 63 (step SF905).

Returning to the description of the RAM clearing process (FIG. 250), after executing the target address adding process (step SF803), it is determined whether the carry flag 516 of the main CPU 63 is set to “1” (step SF804). ). When the carry flag 516 is not set to "1" (step SF804: NO), the target address clearing process (step SF802) and the target address adding process (step SF803) are executed again. When carry flag 516 is set to "1" (step SF804: YES), it is determined whether or not the work completion flag provided to main CPU 63 is set to "1" (step SF805). The work completion flag is a flag for the main CPU 63 to specify whether or not the clearing process for the work area 221 for specific control is completed.

When the work completion flag is not set to "1" (step SF805: NO), after setting the work completion flag to "1" (step SF806), the start address Y (of the stack area 222 for specific control) l) is set as the target address (step SF807). In this case, the address data corresponding to the current start address is set in each of the upper byte 515a and the lower byte 515b in the address counter 515 of the main CPU 63. That is, the upper 8 bits of the present start address are set in the upper byte 515a, and the lower 8 bits of the present start address are set in the lower byte 515b. In step SF807, carry flag 516 is cleared to "0".

After that, the processes of steps SF802 to SF804 are repeated until the carry flag 516 is set to “1” in the process of adding the target address in step SF803. When the carry flag 516 is set to "1" and the work completion flag is set to "1" (step SF804 and step SF805: YES), the main RAM 65 is initialized (step SF808). After that, various registers of the main CPU 63 are cleared to "0" (step SF809), and the initial setting of the various registers is executed (step SF810). In this initial setting, the same processing as the internal function register setting processing of step SF502 in the main processing (FIG. 245) is executed.

Next, the clearing process for non-specific control executed by the main CPU 63 will be described.

In this embodiment, similarly to the 25th embodiment, another monitoring process (step S6009) is executed in the management execution process (FIG. 94). In the separate monitoring process, the monitoring process of the work area 223 for non-specific control and the monitoring process of the stack area 224 for non-specific control are executed. The processing content of the monitoring processing of the work area 223 for non-specific control is the same as step S5405 in the above-mentioned twenty-second embodiment, and the processing content of the monitoring processing of the stack area 224 for non-specific control is the above-mentioned twenty-second embodiment. This is the same as step S5407 in. When it is determined that there is an abnormality in these monitoring processes, a clear process for non-specific control is executed. FIG. 252 is a flowchart showing the clear processing for non-specific control. Note that the processes of steps SG101 to SG107 in the non-specific control clearing process are executed by using the non-specific control program and the non-specific control data in the main CPU 63.

First, Y(m), which is the start address of the work area 221 for non-specific control, is set as the target address (step SG101). In this case, the address data corresponding to the current start address is set in each of the upper byte 515a and the lower byte 515b in the address counter 515 of the main CPU 63. That is, the upper 8 bits of the present start address are set in the upper byte 515a, and the lower 8 bits of the present start address are set in the lower byte 515b. In step SG101, carry flag 516 is cleared to "0" and the work completion flag provided on main CPU 63 is cleared to "0".

After that, the area corresponding to the target address in the main RAM 65 is cleared to "0" (step SG102). Then, the process of adding the target address is executed (step SG103). In this case, a sub-routine for non-specific control stored in the main side ROM 64 is called in order to execute the process of adding the target address. The processing content of the target address addition processing is the same as the processing content of the flowchart shown in FIG. That is, "1" is added to the lower byte 515b in the address counter 515, and if the 8 bits of the lower byte 515b become all zeros after the addition, "1" is set to the carry flag 516 of the main CPU 63. When the carry flag 516 is set to "1", "1" is added to the upper byte 515a in the address counter 515.

Then, it is determined whether or not carry flag 516 is set to "1" (step SG104). When the carry flag 516 is not set to "1" (step SG104: NO), the target address clearing process (step SG102) and the target address adding process (step SG103) are executed again. When carry flag 516 is set to "1" (step SG104: YES), it is determined whether "1" is set to the work completion flag provided in main CPU 63 (step SG105). The work completion flag is a flag for the main CPU 63 to specify whether or not the clear process for the work area 223 for non-specific control is completed.

When the work completion flag is not set to "1" (step SG105: NO), after setting the work completion flag to "1" (step SG106), the start address Y of the stack area 224 for non-specific control is set. (N) is set as the target address (step SG107). In this case, the address data corresponding to the current start address is set in each of the upper byte 515a and the lower byte 515b in the address counter 515 of the main CPU 63. That is, the upper 8 bits of the present start address are set in the upper byte 515a, and the lower 8 bits of the present start address are set in the lower byte 515b. In step SG107, carry flag 516 is cleared to "0".

Then, the processes of steps SG102 to SG104 are repeated until the carry flag 516 is set to "1" in the addition process of the target address in step SG103. When the carry flag 516 is set to "1" and the work completion flag is set to "1" (steps SG104 and SG105: YES), the clear process for the non-specific control ends. ..

Next, the checksum calculation process executed by the main CPU 63 will be described with reference to the flowchart in FIG. The checksum calculation process is performed in the power failure process and is also performed in step SF505 of the main process (FIG. 245). The processes of steps SG201 to SG208 in the checksum calculation process are executed by using the specific control program and the specific control data in the main CPU 63.

First, in the work area 221 for specific control, an addition start address that is a start address when executing the chuck sum calculation process is set to the target address (step SG201). In this case, the address data corresponding to the current addition start address is set in each of the upper byte 515a and the lower byte 515b in the address counter 515 of the main CPU 63. That is, the upper 8 bits of the current addition start address are set in the upper byte 515a, and the lower 8 bits of the current addition start address are set in the lower byte 515b. A setting reference area 341 is set in an area corresponding to the start address of the work area 221 for specific control, and a checksum calculation process in a power failure process is performed in an area of an address next to the area. The total counter at the time of power failure is set to store the checksum information calculated in the above, and the area of the address next to the area is calculated in the checksum calculation processing in the main processing. A total counter at power recovery for storing checksum information is set. The addition start address is set to the address in the next order with respect to the total counter at power recovery. As a result, the setting reference area 341, the power outage total counter, and the power recovery total counter can be excluded from the checksum calculation target in the checksum calculation processing. In step SG201, carry flag 516 is cleared to "0" and the work completion flag provided in main CPU 63 is cleared to "0".

After that, the data of the target address in the main RAM 65 is read (step SG202), and the numerical information of the read data is added to the total counter (in the main process (FIG. 245) provided in the work area 221 for specific control in the main RAM 65. If it is a checksum calculation process, it is added to the total counter at power recovery, and if it is a checksum calculation process in power failure process, it is added to the total counter at power failure) (step SG203). Then, the process of adding the target address is executed (step SG204). In this case, a common subroutine stored in the main ROM 64 for specific control is called in order to execute the process of adding the target address. The processing content of the target address addition processing is the same as the processing content of the flowchart shown in FIG. That is, "1" is added to the lower byte 515b in the address counter 515, and if the 8 bits of the lower byte 515b become all zeros after the addition, "1" is set to the carry flag 516 of the main CPU 63. When the carry flag 516 is set to "1", "1" is added to the upper byte 515a in the address counter 515.

Then, it is determined whether or not carry flag 516 is set to "1" (step SG205). When carry flag 516 is not set to "1" (step SG205: NO), the processes of steps SG202 to SG204 are executed again. When the carry flag 516 is set to "1" (step SG205: YES), it is determined whether the work completion flag of the main CPU 63 is set to "1" (step SG206).

When the work completion flag is not set to "1" (step SG206: NO), after setting the work completion flag to "1" (step SG207), the start address Y (of the stack area 222 for specific control) l) is set as the target address (step SG208). In this case, the address data corresponding to the current start address is set in each of the upper byte 515a and the lower byte 515b in the address counter 515 of the main CPU 63. That is, the upper 8 bits of the present start address are set in the upper byte 515a, and the lower 8 bits of the present start address are set in the lower byte 515b. In step SG208, carry flag 516 is cleared to "0".

Then, the processes of steps SG202 to SG205 are repeated until the carry flag 516 is set to "1" in the addition process of the target address in step SG204. When the carry flag 516 is set to "1" and the work completion flag is set to "1" (steps SG205 and SG206: YES), this checksum calculation process ends.

Next, the effect control process executed by the sound-light side CPU 353 will be described with reference to the flowchart in FIG. The effect control process is executed when the supply of operating power to the sound-light side CPU 353 is started.

When the update start command is received from the main CPU 63 (step SG301: YES), the update notification setting process is executed (step SG302). As described above, the update start command is transmitted to the sound/light side CPU 353 when the setting value update processing (FIG. 247) is started by the main side CPU 63. In the update notification setting process, an image showing that the set value update process (FIG. 247) is being executed, an image for making it possible to recognize the operation content for changing the set value, and the set value update process ( The display control device 82 is controlled so that an image for making it possible to recognize the operation content for ending (FIG. 247) is displayed on the symbol display device 41. This allows the manager of the game hall to recognize that the setting value is being changed, and the operation content and the setting value update processing necessary to change the setting value (FIG. 247). It becomes possible for the manager of the game hall to recognize the operation content necessary for ending the game. In addition to or instead of the above-mentioned notification being performed by the symbol display device 41, at least one of the display light emitting unit 53 and the speaker unit 54 may be configured.

When the confirmation start command is received from the main CPU 63 (step SG303: YES), the confirmation notification setting process is executed (step SG304). As described above, the confirmation start command is transmitted to the sound/light side CPU 353 when the setting confirmation process (FIG. 246) is started by the main CPU 63. In the confirmation notification setting process, an image showing that the setting confirmation process (FIG. 246) is being executed and an image for making it possible to recognize the operation content for ending the setting confirmation process (FIG. 246) are displayed. The display control device 82 controls the display so that it is displayed on the symbol display device 41. This allows the manager of the gaming hall to recognize that the current setting value of the pachinko machine 10 is being confirmed, and is necessary for ending the setting confirmation process (FIG. 246). It is possible for the manager of the game hall to recognize various operation contents. In addition to or instead of the above-mentioned notification being performed by the symbol display device 41, at least one of the display light emitting unit 53 and the speaker unit 54 may be configured.

When the abnormality command is received from the main CPU 63 (step SG305: YES), the abnormality notification setting process is executed (step SG306). As described above, the abnormality command is transmitted to the sound-light side CPU 353 when it is specified that an abnormality has occurred with respect to the power failure flag, the checksum, or the set value at the start of supplying the operating power. In the abnormality notification setting process, the display light emitting unit 53 is caused to emit light in a manner corresponding to the information abnormality at the start of the supply of the operating power, and the speaker unit 54 outputs the voice "Please change the setting." Further, the display control device 82 is controlled so that the character image "Please change the setting." is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are ended when the supply of operating power to the pachinko machine 10 is stopped. However, even if the supply of the operating power to the pachinko machine 10 is temporarily stopped, the above notification is given when the supply of the operating power to the pachinko machine 10 is restarted until the setting value update processing (FIG. 247) is executed. It will be started again.

When the processes of steps SG301 to SG306 are executed, it is determined whether any of the normal restoration command, the clear restoration command, the confirmation restoration command, and the update restoration command are received from the main CPU 63 ( Step SG307). The normal recovery command is a process at the start of supply of operating power (step SF501 to step SF501) without executing the RAM clear process (step SF518), the setting confirmation process (FIG. 246), and the set value update process (FIG. 247). Sent when step SF523) ends. The return command at the time of clear is transmitted when the RAM clear processing (step SF518) is executed and the processing at the start of supplying the operating power (step SF501 to step SF523) is completed. The return command at the time of confirmation is transmitted when the setting confirmation process (FIG. 246) is executed and the process at the start of supply of operating power (steps SF501 to SF523) is completed. The update return command is transmitted when the set value update process (FIG. 247) is executed and the process at the start of supplying the operating power (steps SF501 to SF523) is completed.

If these return commands have not been received (step SG307: NO), the process returns to step SG301. The main CPU 63 transmits one of the return commands to the sound-light CPU 353 when the process at the start of supplying the operating power (step SF501 to step SF523) ends normally. In this case, as described above, the sound-light side CPU 353 does not execute the processing from step SG308 until any of the return commands is received from the main side CPU 63. As a result, while the main CPU 63 is executing the processing (steps SF501 to SF523) at the time of starting the supply of operating power, the sound/light side CPU 353 can be prevented from starting the execution control of the normal effect. In addition, when the main CPU 63 does not normally complete the process (step SF501 to step SF523) at the time of starting the supply of the operating power, the sound-light side CPU 353 does not start the execution control of the normal effect. It becomes possible to do so.

Further, in a situation where no return command is received, there is a possibility that an update start command, a confirmation start command, or an abnormal command will be received from the main CPU 63, and when an update start command is received, the setting will be performed as described above. The notification corresponding to the execution of the value update processing (FIG. 247) needs to be performed. When the confirmation start command is received, the setting confirmation processing (FIG. 246) is executed as already described. It is necessary to make notification that corresponds to that, and when an abnormal command is received, it is necessary to make abnormality notification as described above. In this case, the sound-light side CPU 353 does not execute the processing of step SG206 and thereafter until it receives any return command from the main side CPU 63, so that when the update start command, the confirmation start command, or the abnormal command is received, It is possible to suitably start the corresponding notification.

When any return command is received from the main CPU 63 (step SG307: YES), information corresponding to the standby period (specifically 2 seconds) is set in the standby counter provided in the sound/light side RAM 355 (step). SG308). The information of the waiting period set in the waiting counter is decremented by 1 in the interrupt process activated periodically (specifically, 4 milliseconds) in the sound-light side CPU 353.

After that, the processing corresponding to the type of the return command is executed (step SG309). Specifically, similar to the forty-ninth embodiment, when the normal recovery command is received, the current date and time information of the RTC 356 is read out, and the read out date and time information is stored in the RTC memory 357. As a result, the RTC memory 357 stores the date and time information serving as a reference when specifying the timing for executing the time-based effect.

When the return command received this time is a return command at the time of update, the update end notification process is executed. As described above, the return command at the time of updating is transmitted to the sound/light side CPU 353 when the setting value updating process (FIG. 247) is completed by the main side CPU 63. In the update notification end processing, the notification corresponding to the setting value update processing (FIG. 247) started in step SG302 is ended.

If the return command received this time is the return command for confirmation, the confirmation notification end processing is executed. The return command for confirmation is transmitted to the sound/light side CPU 353 when the main side CPU 63 completes the setting confirmation process (FIG. 246) as described above. In the confirmation notification ending process, the notification corresponding to the setting confirmation process (FIG. 246) started in step SG304 is ended.

After that, it is determined whether the standby period has elapsed by determining whether the value of the standby counter of the sound-light side RAM 355 is "0" (step SG310). When the value of the standby counter is not "0" (step SG310: NO), the process of step SG310 is executed again. As a result, it is possible to prevent the processing after step SG311 in the effect control processing (FIG. 252) from being executed until the waiting period elapses. Even if the process of step SG310 is repeatedly executed, the value of the standby counter is decremented by 1 at the execution timing of the interrupt process.

If an affirmative decision is made in step SG310, an initial operation process is executed (step SG311). In the initial operation process, a drive signal is output to the movable body drive unit 513 so that the movable body 512 arranged at the initial position is moved to the movement limit position and then returned to the initial position. As a result, the movable body 512 moves from the initial position to the movement limit position, and then returns from the movement limit position to the initial position. By checking the operation of the movable body 512, the manager of the game hall can know whether or not the movable body 512 operates normally.

As described above, the sound-light side CPU 353 executes the initial operation process (step SG311) when the standby period elapses from the timing of receiving one of the return commands from the main side CPU 63. As a result, the main CPU 63 performs the initial operation of the movable body 512 after the waiting period elapses after the processing (step SF501 to step SF523) at the time of starting the supply of the operating power is completed. Here, as described above, the main CPU 63 starts the check display on the first to fourth notification display devices 201 to 204 when the processing at the start of supplying the operating power (steps SF501 to SF523) is completed. ..

On the other hand, as described above, the initial operation of the movable body 512 is started when the waiting period elapses from the timing at which one of the return commands is received from the main CPU 63, so that the first to fourth notifications are substantially issued. After the check display is started on the display devices 201 to 204, the initial operation of the movable body 512 is started. Therefore, when the supply of the operating power to the main CPU 63 and the sound-light side CPU 353 is started, the first CPU 63 first completes the processing at the start of the supply of the operating power (step SF501 to step SF523). The check display on the fourth notification display devices 201 to 204 is started, and after that, the movable body 512 starts the initial operation after the waiting period has elapsed. Therefore, when checking the operation of the pachinko machine 10 at the time of shipment from the factory or the daily operation check of the pachinko machine 10 in the game hall, first open the game machine main body 12 in front of the pachinko machine 10 to open the game machine main body 12. After confirming whether the first to fourth notification display devices 201 to 204 normally operate in the state where the back side is exposed, the gaming machine main body 12 is closed and the movable body 512 is moved from the front side of the gaming machine main body 12. It will be possible to confirm whether or not is operating normally.

After executing the initial operation process (step SG311), other processes are repeatedly executed (step SG312). In other processing, when the command to start the game use effect is received from the main CPU 63, the symbol display device 41, the display light emitting unit 53, and the speaker unit 54 are used to start the game use effect. When the settings are made and the situation for the game use is to be advanced, the settings for advancing the game use effect are made by the symbol display device 41, the display light emitting section 53 and the speaker section 54, and the game time is set. When it is a situation in which the effect for use is to be ended, the pattern display device 41, the display light emitting unit 53, and the speaker unit 54 are set to end the effect for game play. In this case, in the case where the execution of the effect for moving the movable body 512 is instructed in the middle of the effect for game play, the movable object 512 is moved from the initial position to the movement limit position and then returned to the initial position. Set. Further, in other processing, when a command to start the effect for the opening/closing execution mode is received from the main CPU 63, the effect for the opening/closing execution mode is provided by the symbol display device 41, the display light emitting unit 53, and the speaker unit 54. In order to proceed with the opening/closing execution mode effect by the symbol display device 41, the display light emitting unit 53, and the speaker unit 54, when the setting for starting is performed and the effect for the opening/closing execution mode is to be advanced. When the setting is performed and the effect for the opening/closing execution mode is to be ended, the symbol display device 41, the display light emitting unit 53, and the speaker unit 54 are set for ending the effect for the opening/closing execution mode. In this case, when the execution of the effect for operating the movable body 512 is instructed in the middle of the effect for the opening/closing execution mode, the movable object 512 is moved from the initial position to the movement limit position and then returned to the initial position. Settings for.

Next, when the supply of operating power to the main CPU 63 and the sound/light CPU 353 is started, the check display is executed on the first to fourth notification display devices 201 to 204, and the movable body 512 is operated. The manner in which the initial operation is executed will be described with reference to the time chart in FIG. FIG. 255(a) shows a period during which the processing (step SF501 to step SF523) at the time of starting the supply of the operating power is being executed in the main CPU 63, and FIG. 255(b) is the setting confirmation processing in the main CPU 63 (FIG. 246) or the set value updating process (FIG. 247) is being executed, and FIG. 255(c) shows the timing at which the sound-light side CPU 353 receives one of the return commands transmitted from the main CPU 63. 255(d) shows the execution period of the initial check period in which the check display is performed on the first to fourth notification display devices 201-204, and FIG. 255(e) waits at the sound-light side CPU 353. 255(f) shows a period during which the initial operation of the movable body 512 is executed.

First, in the process at the start of supply of operating power (steps SF501 to SF523), neither the RAM clear process (step SF518), the setting confirmation process (FIG. 246) nor the set value update process (FIG. 247) is executed. Will be described.

At the timing of t1, supply of operating power to the main CPU 63 and the sound/light side CPU 353 is started. In this case, as shown in FIG. 255(a), the main CPU 63 starts the process (steps SF501 to SF523) at the start of supplying the operating power at the timing t1. Note that the display of the image is started on the symbol display device 41 at the timing of t1. At the start of the supply of operating power this time, none of the "RAM clear operation", "setting change operation" and "setting confirmation operation" is executed. Therefore, the RAM clear process (step SF518), the setting confirmation process (FIG. 246), and the set value update process (FIG. 247) are not executed, and the process at the time of starting the supply of the operating power at the timing of t2 (step) SF501 to step SF523) are completed. In this case, the check display is started on the first to fourth notification display devices 201 to 204 as shown in FIG. 255(d) at the timing of t2. Specifically, all the display segments 321 to 324 of the first to fourth notification display devices 201 to 204 are maintained in the light emitting state. However, as a check display, all the display segments 321 to 324 of the first to fourth notification display devices 201 to 204 may be displayed in a blinking manner.

Further, as shown in FIG. 255(c), a normal return command is transmitted from the main CPU 63 at the timing of t2, and the normal light return command is received by the sound/light side CPU 353. Upon receiving the normal return command, the sound-light side CPU 353 starts measuring the standby period at the timing of t2 as shown in FIG. 255(e). When the waiting period elapses as shown in FIG. 255(e) at the timing of t3 which is in the middle of displaying the check display on the first to fourth notification display devices 201 to 204, the timing shown in FIG. As shown in (f), the initial operation of the movable body 512 is started.

After that, at the timing of t4, the check display on the first to fourth notification display devices 201 to 204 is ended as shown in FIG. 255(d). Further, at the subsequent timing of t5, the initial operation of the movable body 512 is ended as shown in FIG. 255(f).

Next, a case where the setting confirmation process (FIG. 246) or the setting value update process (FIG. 247) is executed in the process (steps SF501 to SF523) at the start of supplying the operating power will be described.

Supply of operating power to the main CPU 63 and the sound/light CPU 353 is started at the timing of t6. In this case, as shown in FIG. 255(a), at the timing of t6, the main CPU 63 starts the processing (steps SF501 to SF523) at the start of supplying the operating power. Note that the display of the image is started on the symbol display device 41 at the timing of t6. At the start of the supply of the operating power this time, the “setting change operation” or the “setting confirmation operation” is executed. Therefore, as shown in FIG. 255(b), the setting confirmation process (FIG. 246) or the set value update process (FIG. 247) is executed from the timing t7 to the timing t8.

As shown in FIG. 255(b), at the timing of t8, the setting related process which is the current execution target of the setting confirmation process (FIG. 246) and the setting value update process (FIG. 247) is ended. ), the process at the start of supplying the operating power (steps SF501 to SF523) ends. In this case, the check display is started on the first to fourth notification display devices 201 to 204 as shown in FIG. 255(d) at the timing of t8. Specifically, all the display segments 321 to 324 of the first to fourth notification display devices 201 to 204 are maintained in the light emitting state. However, as a check display, all the display segments 321 to 324 of the first to fourth notification display devices 201 to 204 may be displayed in a blinking manner.

Further, at the timing of t8, as shown in FIG. 255(c), the main CPU 63 transmits a return command for confirmation or a return command for updating, and the return command is received by the sound/light side CPU 353. Upon receiving the return command, the sound-light side CPU 353 starts measuring the waiting period at the timing of t8 as shown in FIG. 255(e). Then, the waiting period elapses as shown in FIG. 255(e) at the timing of t9 during which the check display is being performed on the first to fourth notification display devices 201 to 204, and accordingly, as shown in FIG. As shown in (f), the initial operation of the movable body 512 is started.

After that, at the timing of t10, the check display on the first to fourth notification display devices 201 to 204 is ended as shown in FIG. 255(d). Further, at the subsequent timing of t11, the initial operation of the movable body 512 is ended as shown in FIG. 255(f).

According to this embodiment described in detail above, the following excellent effects are exhibited.

When the RAM clear process (FIG. 250), the non-specific control clear process (FIG. 251), and the checksum calculation process (FIG. 252) are executed, the target address is sequentially updated, and the target after the update is executed. The "0" clearing process or the checksum calculating process is executed for the area of the main side RAM 65 corresponding to the address (these processes are also referred to as a specifying process hereinafter). As a result, it becomes possible to sequentially perform the specific processing on a plurality of areas in the main RAM 65. In this case, when the updated target address becomes the reference address (specific address), the carry flag 516 of the main CPU 63 is set to "1", and the carry flag 516 is set to "1". In that case, the execution of the specific process is terminated. As a result, when specifying whether or not the execution of the specifying process is completed for all the areas of the main RAM 65 to be executed, it is only necessary to specify whether or not "1" is set in the carry flag 516. Therefore, it is possible to reduce the processing load for performing the identification.

In a configuration in which a plurality of reference addresses are present, the carry flag 516 is set to "0" for any reference address by updating the target address in the situation where the address immediately before the reference address is set as the target address. 1” is the address to be set. This makes it possible to specify whether or not the execution of the specific process is completed by specifying whether or not "1" is set in the carry flag 516 regardless of which reference address is used as the reference. Is possible.

The target address is set in the address counter 515 of the main CPU 63. The address counter 515 includes an upper byte 515a and a lower byte 515b. When the target address is updated, "1" is added to the lower byte 515b. However, in the situation where all "1" is set as the maximum value in the lower byte 515b, "1" is added to the lower byte 515b. Is added, it is necessary to add "1" to the upper byte 515a while the lower byte 515b is set to the minimum value of all zeros. In this case, since the carry flag 516 is set to "1" when the lower byte 515b is changed from the maximum value to the minimum value, it is specified whether or not the carry flag 516 is set to "1". This makes it possible to specify whether or not it is necessary to add "1" to the upper byte 515a. By specifying whether or not "1" is set in the carry flag 516 in the configuration, it is specified whether or not the execution of the specific processing is completed for all the areas of the main RAM 65 to be executed. It becomes possible to do. As a result, the configuration for identifying whether or not it is necessary to add “1” to the upper byte 515a can be used to perform the identifying process on all the areas of the main RAM 65 to be executed. It is possible to specify whether or not it is completed.

The work area 221 for specific control, the stack area 222 for specific control, the work area 223 for non-specific control, and the stack area 224 for non-specific control are all in the last order address in the address range of the main RAM 65. The lower byte 515b has the maximum value. Thus, by confirming whether or not "1" is set in the carry flag 516 of the main CPU 63 for each of the areas 221 to 224, it is possible to specify whether or not the execution of the specific processing is completed. Is possible. Therefore, it is possible to reduce the processing load for identifying whether or not the execution of the identifying process is completed.

In the configuration in which the RAM clear process (FIG. 250), the clear process for non-specific control (FIG. 251), and the checksum calculation process (FIG. 252) are set as the specific processes, any of these specific processes is executed. Even when there is a situation, by specifying whether or not “1” is set in the carry flag 516 of the main CPU 63, it is possible to specify the end timing of the specifying process. Therefore, it is possible to simplify the processing configuration for specifying the termination timing of the specific processing.

Since the initial operation of the movable body 512 is performed when the supply of the operating power is started, it is possible to confirm whether or not the movable body 512 operates normally when the supply of the operating power is started. In this case, since the start timing of the initial operation in the movable body 512 is delayed, it is not necessary to confirm the initial operation immediately after the supply of the operating power is started, and the initial operation can be confirmed with a margin. It becomes possible to do.

When the supply of the operating power is started, the check display is performed on the first to fourth notification display devices 201 to 204. Therefore, at the start of the supply of the operating power, the first to fourth notification display devices 201 to 201 It becomes possible to confirm whether or not the 204 operates normally. Further, since the first to fourth notification display devices 201 to 204 are visible by exposing the back side of the pachinko machine 10, the movable body 512 is visible from the front side of the pachinko machine 10. In order to confirm each of the check display of the first to fourth notification display devices 201 to 204 and the initial operation of the movable body 512, it is necessary to visually recognize each of the back side and the front side of the pachinko machine 10. In this case, the start timing of the initial operation of the movable body 512 is delayed. Thereby, after the back side of the pachinko machine 10 is exposed and the check display on the first to fourth notification display devices 201 to 204 is confirmed, the game machine main body 12 is closed and the initial operation of the movable body 512 is confirmed. Therefore, it is possible to suitably confirm each initial operation.

By measuring the waiting period, the initial operation of the movable body 512 is delayed. As a result, the processing configuration for delaying the initial operation of the movable body 512 can be simplified.

The waiting period is measured with reference to the timing of receiving the return command transmitted from the main CPU 63. This makes it possible to delay the initial operation of the movable body 512 based on the progress of control in the main CPU 63. Further, the main CPU 63 transmits a return command when the process at the start of supplying the operating power (step SF501 to step SF523) is completed. This makes it possible to delay the initial operation of the movable body 512 with reference to the timing when the processing (step SF501 to step SF523) at the start of supplying the operating power in the main CPU 63 is completed.

Since the main CPU 63 transmits different types of return commands according to the execution contents of the process (step SF501 to step SF523) at the time of starting the supply of the operating power, the sound-light side CPU 353 starts the supply of the operating power at the main CPU 63. It is possible to execute the control according to the execution contents of the process (step SF501 to step SF523). In this case, the standby period for delaying the initial operation of the movable body 512 is set regardless of which type of return command is transmitted, and therefore, the process at the time of starting the supply of the operating power in the main CPU 63. It is possible to delay the initial operation of the movable body 512 regardless of the content of execution of (step SF501 to step SF523).

The movable body 512 performs the initial operation after the sound-light side CPU 353 receives the return command transmitted when the processing at the start of supplying the operating power (step SF501 to step SF523) is executed in the main CPU 63. As a result, it is possible to cause the movable body 512 to perform the initial operation after the main CPU 63 executes the processing (step SF501 to step SF523) at the start of supplying the operating power. Further, the main CPU 63 transmits a return command when the process at the start of supplying the operating power (step SF501 to step SF523) is completed. As a result, the movable body 512 can be caused to perform an initial operation with reference to the timing when the processing (step SF501 to step SF523) at the time of starting the supply of the operating power in the main CPU 63 is completed.

It should be noted that the target address is not limited to the addition method, and the subtraction method may be used. In this case, when the target address is updated, the value of the lower byte 515b of the address counter 515 is decremented by "1". When the value of the lower byte 515b is decremented by "1" in the situation where the 8 bits of the lower byte 515b are all zeros (that is, the numerical information of the lower byte 515b is the minimum value), the carry flag of the main CPU 63 "1" is set in 516 and the value of the upper byte 515a is subtracted by "1". In this configuration, the lower byte in the last sequential address in each address range of the specific control work area 221, the specific control stack area 222, the non-specific control work area 223, and the non-specific control stack area 224. By making the configuration in which the carry flag 516 is set to "1" by configuring the 515b to be all zeros, all the areas of the main RAM 65 that are execution targets are execution targets of the specific processing. It becomes possible to specify whether or not

Further, when the target address is updated, the updating numerical value added to or subtracted from the lower byte 515b is not limited to "1", and may be "2" or "3". It may be present or may be "4".

Further, instead of the configuration in which the carry flag 516 is set to "1" when the numerical information of the lower byte 515b is changed from one of the minimum value and the maximum value to the other, it is higher than the least significant bit of the upper byte 515a. The carry flag 516 may be set to "1" when the value of a predetermined bit on the side is changed. In the configuration, the last-order address in each address range of the work area 221, the stack area 222 for specific control, the work area 223 for non-specific control, and the stack area 224 for non-specific control is The address of which the numerical value of the predetermined bit is changed when the address of the last order is updated to the address of the next order. As a result, by specifying whether or not "1" is set in the carry flag 516, it is specified whether or not all the areas of the main RAM 65 that are the execution targets are the execution targets of the specific processing. It becomes possible.

The address of the main RAM 65 is not limited to 2 bytes, and may be 1 byte, 3 bytes, or 4 bytes or more. In the case of 3 bytes, the carry flag 516 may be set to "1" when a carry occurs from the lower 2 bytes to the upper 1 byte. In the configuration, the last-order address in each address range of the specific control work area 221, the specific control stack area 222, the non-specific control work area 223, and the non-specific control stack area 224 is The address is such that when the address of the last order is updated to the address of the next order, a carry from the lower 2 bytes to the upper 1 byte occurs. As a result, by specifying whether or not "1" is set in the carry flag 516, it is specified whether or not all the areas of the main RAM 65 that are the execution targets are the execution targets of the specific processing. It becomes possible.

In the case of 1 byte, the carry flag 516 is set to "1" when the numerical value of a predetermined bit higher than the least significant bit of the 1 byte is changed. In the configuration, the last-order address in each address range of the work area 221, the stack area 222 for specific control, the work area 223 for non-specific control, and the stack area 224 for non-specific control is The address of which the numerical value of the predetermined bit is changed when the address of the last order is updated to the address of the next order. As a result, by specifying whether or not "1" is set in the carry flag 516, it is specified whether or not all the areas of the main RAM 65 that are the execution targets are the execution targets of the specific processing. It becomes possible.

The specific processing is not limited to the configuration in which the specific processing is collectively executed in the specific control work area 221 and the specific control stack area 222, and the specific processing and the specific control for the specific control work area 221 are performed. The specific processing for the stack area 222 may be separately performed. Even in this case, by specifying whether or not “1” is set in the carry flag 516 in each specific process, it is possible to specify whether or not the execution of the specific process is completed. Become.

The specific processing is not limited to the configuration in which the specific processing is collectively executed in the work area 223 for non-specific control and the stack area 224 for non-specific control. The specific processing for the stack area 224 for non-specific control may be separately performed. Even in this case, by specifying whether or not “1” is set in the carry flag 516 in each specific process, it is possible to specify whether or not the execution of the specific process is completed. Become.

The blank area is not limited to the configuration in which the blank area is set in the address between the specific control work area 221 and the specific control stack area 222 in the main RAM 65, and the specific control work area 221 is not limited thereto. The stack area 222 for specific control and the stack area 222 for specific control may be set to have continuous addresses. In this case, the last address in the rear area of the specific control work area 221 and the specific control stack area 222 is set to "1" in the carry flag 516 when the address is updated to the next address. When the specific processing is collectively performed on the specific control work area 221 and the specific control stack area 222, whether the carry flag 516 is set to "1" It is possible to specify whether or not the execution of the specifying process is completed by specifying that.

Further, the configuration is not limited to the configuration in which the blank area is set in the address between the work area 223 for non-specific control and the stack area 224 for non-specific control in the main RAM 65. The work area 223 and the stack area 224 for non-specific control may be set to have continuous addresses. In this case, the last sequential address in the rear area of the non-specific control work area 223 and the non-specific control stack area 224 is set to "1" in the carry flag 516 when the address is updated to the next sequential address. By setting the address to be set to “1”, the carry flag 516 is set to “1” when the specific processing is collectively performed on the work area 223 for non-specific control and the stack area 224 for non-specific control. By specifying whether or not the execution of the specific processing is completed, it is possible to specify whether or not the execution of the specific processing is completed.

Further, the number of addresses assigned to the specific control work area 221 may be 257 or more. In this case, not only the last-ordered address in the specific control work area 221, but also the middle-ordered address is an address in which the lower 8 bits are all set to "1". In this configuration, the number of times the carry flag 516 is set to "1" is measured, and the number of times of measurement is the number of addresses where the lower 8 bits of the specific control work area 221 are all "1". The configuration is such that it is determined that the execution of the specific process for the specific control work area 221 is completed when the number of end criteria reaches a certain value. As a result, the carry flag 516 can be used to identify the timing for ending the identification process.

Further, instead of the configuration in which the main CPU 63 uses the program to execute the target address addition processing (FIG. 251), the dedicated circuit may be configured to update the target address. In this case, even when the target address is updated by the dedicated circuit, when the lower byte 515b is changed from one of the minimum value and the maximum value to the other, the carry flag 516 is set to "1" and the upper byte 515a. Will be updated. This makes it possible to specify whether or not the execution of the specifying process is completed by specifying whether or not "1" is set in the carry flag 516.

In addition, the last-ordered address in the work area 221, the stack area 222 for specific control, the work area 223 for non-specific control, and the stack area 224 for non-specific control of the specific control work area 221, the lower 8 bits is the maximum. The configuration is not limited to the value, and the configuration may be such that the lower 8 bits are set to the minimum value. In this case, since the carry flag 516 is set to "1" when the address of the last order is updated from the address immediately before to the address of the last order, the carry flag 516 is set to "1". When it is specified that "1" is set, the specifying process is ended after the specifying process is executed for the area of the target address at that time.

In addition, the configuration in which the special process is executed when "1" is set in the carry flag 516 is used to specify whether or not the specific process is executed for all areas of the target address. You may use it.

For example, in a configuration including a random number counter composed of a plurality of bytes, when the numerical information of the lower byte is changed from one of the minimum value and the maximum value to the other, "1" is set in the carry flag 516 and the carry flag 516 is set. When the carry flag 516 is set to "1", the random number counter different from the above random number counter is updated. The configuration may be started. In this case, when updating a plurality of random number counters at the same time, it is possible to shift the update start timing of the random number counters at a constant interval, and only check the carry flag 516 to specify the trigger for shifting at the constant interval. Therefore, the processing load can be reduced.

For example, in a configuration including a timer counter composed of a plurality of bytes, when the numerical information of the lower byte is changed from one of the minimum value and the maximum value to the other, "1" is set to the carry flag 516 and the carry flag 516 is set. When "1" is set, the numerical information of the upper byte is configured to be updated, and when "1" is set to carry flag 516, a timer counter different from the above timer counter measures the period. May be started. In this case, when measuring a plurality of periods using a plurality of timer counters, it is possible to shift the measurement start timing of each period at a constant interval, and when specifying the trigger to shift at the constant interval, carry Since it is sufficient to check the flag 516, the processing load can be reduced.

Further, when the supply of the operating power is started, the start timing of the initial operation of the movable body 512 is delayed, so that the check display on the first to fourth notification display devices 201 to 204 is started and then the movable body 512 is moved. The initial operation of the movable body 512 is not limited to the configuration in which the initial operation of the movable body 512 is started, and the start timing of the check display of the first to fourth notification display devices 201 to 204 is delayed. The check display on the first to fourth notification display devices 201 to 204 may be started after the start.

Further, when the supply of the operating power is started, the start timing of the initial operation of the movable body 512 is delayed, so that the check display on the first to fourth notification display devices 201 to 204 is started and then the movable body 512 is moved. In the configuration in which the initial operation of the body 512 is started, the initial operation of the movable body 512 may be started after the timing at which the check display on the first to fourth notification display devices 201 to 204 ends.

In addition, the start timing of the initial operation of the movable body 512 may not be delayed. That is, when the main CPU 63 executes the process at the start of supplying the operating power (steps SF501 to SF523) and transmits the return command, the initial operation of the movable body 512 starts at the timing when the return command is received. It may be configured to be. In this case, although the start timing of the initial operation of the movable body 512 is not delayed, the main CPU 63 starts the initial operation of the movable body 512 at the timing when the process (step SF501 to step SF523) at the time of starting the supply of the operating power is completed. It becomes possible to do. In the configuration, whether or not the setting confirmation process (FIG. 246) or the set value update process (FIG. 247) is executed in the process (step SF501 to step SF523) at the time of starting the supply of the operating power of the main CPU 63. Accordingly, the timing when the initial operation of the movable body 512 is started is different. In other words, when the setting confirmation process (FIG. 246) and the setting value update process (FIG. 247) are not executed, the initial operation of the movable body 512 is immediately started when the supply of the operating power is started. Then, when the setting confirmation process (FIG. 246) or the set value update process (FIG. 247) is executed, the initial operation of the movable body 512 starts at a timing delayed with respect to the timing when the supply of the operating power is started. To be done.

Further, when the start timing of the initial operation is delayed when the supply of the operating power is started or when the process at the start of supplying the operating power (step SF501 to step SF523) is completed in the main CPU 63, the initial operation is completed. The object to be executed is not limited to the movable body 512 and is arbitrary. For example, in addition to or instead of the movable body 512, any of the display light emitting unit 53, the speaker unit 54, and the symbol display device 41 may be used. Further, for all control targets controlled by the sound-light side CPU 353, the start timing of the initial operation is delayed when the supply of the operating power is started, or the process at the time of starting the supply of the operating power in the main CPU 63 ( The initial operation may be executed when Steps SF501 to SF523) are completed.

<73rd Embodiment>
In this embodiment, the contents of the effect control process executed by the sound-light side CPU 253 are different from those in the 72nd embodiment. The configuration different from that of the 72nd embodiment will be described below. The description of the same configuration as the 72nd embodiment is basically omitted.

FIG. 256 is a flowchart showing the effect control process in this embodiment.

In steps SG401 to SG406, the same processing as step SG301 to step SG306 of the effect control processing (FIG. 254) in the above-mentioned 72nd embodiment is executed. When the processes of steps SG401 to SG406 are executed, it is determined whether any of the normal restoration command, the clear restoration command, the confirmation restoration command, and the update restoration command are received from the main CPU 63 ( Step SG407). When these return commands have not been received (step SG407: NO), the process returns to step SG401.

When any return command is received from the main CPU 63 (step SG407: YES), the process corresponding to the type of the return command is executed (step SG408). The processing content of this processing is the same as the processing of step SG309 of the effect control processing (FIG. 254) in the 72nd embodiment.

Then, on condition that the return command received this time is a return command different from the normal return command, that is, a return command for clear, a return command for confirmation, and a return command for update (step SG409: NO). Information corresponding to the standby period (specifically, 2 seconds) is set in the standby counter provided in the sound/light side RAM 355 (step SG410). The information of the waiting period set in the waiting counter is decremented by 1 in the interrupt process activated periodically (specifically, 4 milliseconds) in the sound-light side CPU 353.

After that, it is determined whether or not the standby period has elapsed by determining whether or not the value of the standby counter of the sound-light side RAM 355 is "0" (step SG411). When the value of the standby counter is not "0" (step SG411: NO), the process of step SG411 is executed again. Accordingly, when any one of the return command for clear, the return command for confirmation, and the return command for update is received from the main CPU 63, step SG412 in the effect control process (FIG. 256) until the waiting period elapses. It is possible to prevent the subsequent processing from being executed. Even if the process of step SG411 is repeatedly executed, the value of the standby counter is decremented by 1 at the execution timing of the interrupt process.

If an affirmative decision is made in step SG409, or if an affirmative decision is made in step SG411, an initial operation process is executed (step SG412). In the initial operation process, a drive signal is output to the movable body drive unit 513 so that the movable body 512 arranged at the initial position is moved to the movement limit position and then returned to the initial position. As a result, the movable body 512 moves from the initial position to the movement limit position, and then returns from the movement limit position to the initial position. By checking the operation of the movable body 512, the manager of the game hall can know whether or not the movable body 512 operates normally.

After that, other processing is executed (step SG413). The processing content of the other processing is the same as the processing of step SG312 of the effect control processing (FIG. 254) in the 72nd embodiment.

According to the above configuration, the RAM clearing process (step SF518), the setting confirmation process (FIG. 246) and the setting value updating process (FIG. 247) in the process (steps SF501 to SF523) at the start of supplying the operating power in the main CPU 63. When any one of the above is executed, the initial operation of the movable body 512 is performed after the standby period is measured by the sound and light side CPU 353, and the process at the start of supplying the operating power in the main side CPU 63 (steps SF501 to SF523). ), if the RAM clear process (step SF518), the setting confirmation process (FIG. 246), and the set value update process (FIG. 247) are not executed, the sound light side CPU 353 measures the waiting period. Without doing so, the initial operation of the movable body 512 is performed. When business is started in the game hall, when the main power supply for supplying operating power to each pachinko machine 10 is switched from the OFF state to the ON state with the power of the pachinko machine 10 being ON-operated. There is. When such a power ON operation is performed, the supply of operating power to the pachinko machine 10 is started without opening the gaming machine main body 12. Then, in such a situation, the RAM clearing process (step SF518), the setting confirmation process (FIG. 246), and the setting value updating process (FIG. 246) in the process (steps SF501 to SF523) at the start of supply of operating power in the main CPU 63 ( 247) is not executed, the initial operation of the movable body 512 is started without measuring the waiting period. This makes it possible to immediately confirm the initial operation of the movable body 512.

On the other hand, when any of the "RAM clear operation", "setting confirmation operation" and "setting change operation" is performed, the game machine main body 12 is opened. Then, in such a situation, the RAM clearing process (step SF518), the setting confirmation process (FIG. 246), and the setting value updating process (FIG. 246) in the process (steps SF501 to SF523) at the start of supply of operating power in the main CPU 63 ( 247) is executed, the initial operation of the movable body 512 is started after the waiting period is measured. As a result, the initial operation of the movable body 512 can be started after the gaming machine body 12 is closed.

Note that the waiting period is not limited to the configuration in which the start timing of the initial operation of the movable body 512 is delayed, and the opening/closing detection sensor indicates that the gaming machine main body 12 has changed from the open state to the closed state. It may be configured to delay the start timing of the initial operation of the movable body 512 by starting the initial operation of the movable body 512 on the condition that it is detected. In this case, it is possible to start the initial operation of the movable body 512 after the gaming machine body 12 is closed.

Further, in the configuration, when the supply of the operating power is started in a state where the gaming machine body 12 is in the closed state, the movable body 512 is not initially operated, but the invention is not limited to this. If the supply of the operating power is started in a state where the gaming machine main body 12 is closed, the main CPU 63 terminates the process (step SF501 to step SF523) at the start of supplying the operating power and returns the return command. The initial operation of the movable body 512 may be started when is transmitted.

Further, in the above configuration, even if the gaming machine main body 12 is changed from the open state to the closed state, if the return command is not received from the main CPU 63 at that time, the initial operation of the movable body 512 is not started. The initial operation of the movable body 512 may be started after receiving the return command. That is, the initial operation of the movable body 512 is started when the return command is received from the main CPU 63 and the gaming machine main body 12 is changed from the open state to the closed state.

Further, in the configuration of the above embodiment, the initial operation of the movable body 512 may not be performed when the normal return command is received. As a result, it is possible to prevent the initial operation of the movable body 512 from being performed when the game hall is opened for business.

<74th Embodiment>
In this embodiment, the processing configuration when the supply of operating power is started is different from that in the 49th embodiment. Hereinafter, a configuration different from that of the 49th embodiment will be described. Note that the description of the same configuration as the 49th embodiment is basically omitted.

FIG. 257 is a flowchart showing the main processing executed in the main CPU 63 in this embodiment. The processes of steps SG501 to SG527 in the main process are executed by using the program for specific control and the data for specific control in the main CPU 63.

First, power-on initialization processing is executed (step SG501). In the power-on initialization process, for example, a predetermined wait time (specifically, 1 second) elapses after the main process is started, and the process waits without proceeding to the next process. In the predetermined period for this weight, the operation start and initial setting of the symbol display device 41 are completed. Also, access to the main RAM 65 is permitted.

Then, the internal function register setting process is executed (step SG502). In the internal function register setting process, as in the 35th embodiment, the interrupt period of the first timer interrupt process (FIG. 133), which is a process that is activated by periodically interrupting the main process, is set to the first interrupt period. (Specifically, 4 ms), and the interrupt period of the second timer interrupt process (FIG. 134), which is a process that is periodically interrupted and activated with respect to the main process, is set from the first interrupt period. Is set to the second interrupt cycle (specifically, 2 milliseconds) which is a short cycle.

That is, in this embodiment, as in the 35th embodiment, the first timer interrupt processing (FIG. 133) and the second timer interrupt processing (FIG. 134) are performed so that the interrupt cycle becomes relatively short as the timer interrupt processing. And exist. Both the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134) are activated by interrupting the main process. The second timer interrupt process (FIG. 134) is activated by interrupting the first timer interrupt process (FIG. 133). On the other hand, the first timer interrupt process (FIG. 133) does not start by interrupting the second timer interrupt process (FIG. 134). In addition, when both the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134) are not executed, and when both the first interrupt cycle and the second interrupt cycle have passed, those cycles The second timer interrupt processing (FIG. 134) is started first regardless of the lapsed order of the above. In this respect, it can be said that the second timer interrupt process (FIG. 134) is a process that is activated prior to the first timer interrupt process (FIG. 133). However, the configuration is not limited to this, and the first timer interrupt process (FIG. 133) may be activated prior to the second timer interrupt process (FIG. 134).

In the internal function register setting process, the first interrupt period of the first timer interrupt process (FIG. 133) is set in a predetermined register of the main CPU 63, and the second interrupt period of the second timer interrupt process (FIG. 134) is set. It is set in a specific register of the side CPU 63. Further, in the internal function register setting process, in addition to the setting of the first and second interrupt cycles, the setting process of the numerical range of various counters such as the numerical range of the hit random number counter C1 is executed.

After that, "1" is set to the startup processing flag provided in the specific control work area 221 (step SG503). As in the 35th embodiment, the start-up processing flag is among the various processes set in the first timer interrupt process (FIG. 133) even if the first timer interrupt process (FIG. 133) is activated. While the power outage monitoring, the processing for updating various counters and the illegality monitoring are executed, the first timer interrupt processing (FIG. 133) should be terminated without executing the processing for advancing the game. This is a flag for specifying by the main CPU 63.

The start-up processing flag is set to "1" when the processing at the start of supplying the operating power (steps SG501 to SG521) is started in the main processing (Fig. 257), and the processing at the start of supplying the operating power is started. “0” is cleared before (steps SG501 to SG521) and the residual process (steps SG524 to SG527) are started. As in the 35th embodiment, in the first timer interrupt process (FIG. 133), when the start-up processing flag is set to "1", the processes of steps S8907 to S8920 are not executed. Therefore, in order to advance the game in a situation where the setting confirmation process (FIG. 258) or the setting value update process (FIG. 259) described later among the processes at the time of starting the supply of the operating power (steps SG501 to SG521) is executed. It is possible to prevent the processing of (1) from being executed. On the other hand, as described above, in the first timer interrupt processing (FIG. 133), even if the start-up processing flag is set to "1", by executing the processing of steps S8901 to S8905, the operating power is reduced. The power failure monitoring is executed even in the situation where the setting confirmation processing (FIG. 258) or the set value update processing (FIG. 259) described later among the processing (steps SG501 to SG521) at the start of the supply of is executed. At the same time, the hit random number counter C1, the big hit type counter C2, the reach random number counter C3, and the random number initial value counter CINI are updated, and further fraud detection is executed.

In particular, even when the start-up processing flag is set to "1", the power failure information storage processing (step S8901) is executed, so that the operation power supply start processing (steps SG501 to SG521) is started. Even if a power failure occurs in the situation where the setting confirmation processing (FIG. 258) or the set value update processing (FIG. 259) described later in (1)) is being executed, the power failure processing can be executed for the power failure. In the power failure process, as in the thirty-fifth embodiment, “1” is set to the power failure flag provided in the work area 221 for specific control, and the checksum calculation process is executed to execute the calculated checksum. Is stored in the work area 221 for specific control, it is possible to prevent the occurrence of an abnormality in the main RAM 65 when the supply of operating power is restarted. As a result, when a power failure occurs during the setting confirmation process (FIG. 258) or the setting value update process (FIG. 259), the fact that a power failure has occurred during these setting-related processes is supplied to the next operating power. It is possible to specify at the start.

Incidentally, in the situation where the setting confirmation process (FIG. 258) or the set value update process (FIG. 259) is being executed, both the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134) are performed. Interrupts are not prohibited and can be interrupted at any timing. In this case, when the first timer interrupt process (FIG. 133) or the second timer interrupt process (FIG. 134) is activated in the setting confirmation process (FIG. 258) or the setting value update process (FIG. 259), The information of the return address of the main process (FIG. 257) for returning after the timer interrupt process that is the activation target is saved is saved in the stack area 222 for specific control, and the timer interrupt process is activated. Information of various registers of the main CPU 63 immediately before is saved in the stack area 222 for specific control. Then, when the timer interrupt process that is the activation target ends, the process returns to the process of the main process (FIG. 257) corresponding to the information of the return address saved in the stack area 222 for specific control, and The information saved in the stack area 222 for specific control is restored to various registers of the main CPU 63.

After "1" is set in the startup processing flag in step SG503, it is determined whether or not "1" is set in the power failure flag provided in the work area 221 for specific control (step SG504). .. When the power failure information storage processing (step S8901) of the first timer interrupt processing (FIG. 133) executes the power failure processing, the power failure flag is set to "1". The power outage flag is a flag for the main CPU 63 to specify whether or not the power outage process was appropriately performed at the previous power off time.

When the power failure flag is set to "1" (step SG504: YES), the checksum is calculated as in the case of the power failure process, and it is determined whether the checksum is normal (step SG505). .. In each of the power failure process and step SG505, checksums are calculated for the specific control work area 221 and the specific control stack area 222. In step SG505, the checksum calculated in the power failure process executed immediately before the supply of the operating power to the main CPU 63 is stopped and stored in the specific control work area 221 is read, and the read check is performed. By comparing the sum with the checksum calculated in step SG505, it is determined whether the checksums match.

If the checksums match (step SG505: YES), is the setting value corresponding to the information stored in the setting reference area 341 (see FIG. 154) in the specific control work area 221 within the normal range? It is determined whether or not (step SG506). The setting reference area 341 is a storage area in which information for specifying the current setting value of the pachinko machine 10 by the main CPU 63 is stored as in the 45th embodiment. When the numerical information of “1” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 1”. When the numerical information of “2” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 2”. When the numerical information of “3” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 3”. When the numerical information of “4” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 4”. When the numerical information of “5” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 5”. When the numerical information of “6” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 6”. In step SG506, it is determined whether or not the setting value information stored in the setting reference area 341 is any one of "1" to "6".

When a positive determination is made in all of step SG504, step SG505 and step SG506, it is determined whether or not "1" is set in the setting update display flag provided in the work area 221 for specific control (step SG507). .. The setting update display flag is a flag for the main CPU 63 to specify that the setting value update processing (FIG. 259) is being executed as in the 35th embodiment, and the setting update display flag is "1". When is set, a display indicating that the setting value is being updated and a setting value being updated are displayed on the first to fourth notification display devices 201 to 204. The setting update display flag is a flag that is set to "1" when the setting value updating process (Fig. 259) is started and is cleared to "0" when the setting value updating process (Fig. 259) is ended. In the situation where the setting value update process (FIG. 259) is not executed, basically, the setting update display flag is not set to "1". However, when the supply of the operating power to the main CPU 63 is stopped in the situation where the setting value updating process (FIG. 259) is being executed, and then the supply of the operating power to the main CPU 63 is started. In, the setting update display flag is set to "1". The state where the setting update display flag is set to "1" is maintained until the process of clearing the setting update display flag to "0" is executed in the setting value update process (FIG. 259).

When the setting update display flag is not set to "1" and a negative determination is made in step SG507, it is determined whether or not the reset button 68c is pressed (step SG508). That is, it is determined whether or not the power of the pachinko machine 10 is turned on while the reset button 68c is being pressed and the supply of operating power to the main CPU 63 is started. Here, in the present embodiment, as in the 35th embodiment, the main control device 60 is provided with the setting key insertion portion 68a and the reset button 68c, but is not provided with the update button 68b.

When the reset button 68c has not been pressed (step SG508: NO), it is determined whether the game stop flag in the specific control work area 221 is set to "1" (step SG509). The game stop flag is a flag that is set to "1" when "1" is not set in the power failure flag, when the checksums do not match, or when the set value is abnormal. When the game stop flag is set to "1", the processes of steps S8901 to S8905 are executed in the first timer interrupt process (FIG. 133), while the positive determination is made in step S8906 to steps S8907 to step. The process of S8920 is not executed. As a result, when the power failure flag is not set to “1” because the power failure process was not properly performed at the previous power shutdown, the work area 221 for the specific control and the stack area 222 for the specific control are If at least one of the checksums does not match due to the change in the information storage state since the last power-off, or if the set value is abnormal, power failure monitoring, updating of various counters and illegal operation While the processing for monitoring is executed, the processing for advancing the game is not executed. When an affirmative determination is made in step SG509, the processes of step SG520 and step SG521 described below are executed.

When a negative determination is made in step SG509, it is determined whether or not the setting key insertion unit 68a has been turned on by using the setting key (step SG510). When the setting key insertion unit 68a is turned on by using the setting key (step SG510: YES), the setting confirmation process is executed (step SG512). Even when the setting key insertion unit 68a is not turned on by using the setting key (step SG510: NO), the setting confirmation display flag provided in the work area 221 for specific control is set to "1". If is set (step SG511: YES), the setting confirmation process is executed (step SG512).

The setting confirmation display flag is a flag for the main CPU 63 to specify that the setting confirmation process (FIG. 258) is being executed as in the 35th embodiment, and the setting confirmation display flag is "1". If is set, a display indicating that the setting value is being confirmed and a display indicating the currently set setting value are displayed on the first to fourth notification display devices 201 to 204. Be seen. The setting confirmation display flag is a flag that is set to “1” when the setting confirmation process (FIG. 258) is started and is cleared to “0” when the setting confirmation process (FIG. 258) is ended. In a situation where the setting confirmation process (FIG. 258) is not executed, basically, the setting confirmation display flag is not set to "1". However, when the supply of the operating power to the main CPU 63 is stopped in the situation where the setting confirmation process (FIG. 258) is being executed, and then the supply of the operating power to the main CPU 63 is started. In, the setting confirmation display flag is set to "1". When the setting confirmation display flag is set to "1", the RAM clearing process (FIG. 260) described later is executed, or the setting confirmation display flag is cleared to "0" in the setting confirmation process (FIG. 258). It is maintained until the process is executed.

Not only when the reset button 68c is not pressed as described above and the setting key insertion portion 68a is ON-operated (that is, when the "setting confirmation operation" is performed), but also when the reset button 68c is operated. The setting confirmation process (FIG. 258) is executed by executing the setting confirmation process (FIG. 258) even when the setting confirmation display flag is set to “1” even when the pressing operation is not performed. When the power failure process is executed under the above condition, the setting confirmation process (FIG. 258) is executed even if the “setting confirmation operation” is not performed when the supply of the operating power is subsequently restarted. As a result, it becomes possible to continuously confirm the current set value of the pachinko machine 10. On the other hand, even when the power failure process is executed in the situation where the setting confirmation process (FIG. 258) is being executed, if the reset button 68c is pressed when restarting the supply of the operating power, Without performing the setting confirmation process (FIG. 258), the RAM clear process (FIG. 260) and the setting value update process (FIG. 259) corresponding to the operation performed when the supply of the operating power is restarted are executed. R. This makes it possible to prioritize the execution of the RAM clear process (FIG. 260) or the set value update process (FIG. 259) over the setting confirmation process (FIG. 258).

Here, the setting confirmation process executed in step SG512 will be described. FIG. 258 is a flowchart showing the setting confirmation processing. The processing of steps SG601 to SG607 in the setting confirmation processing is executed by using the specific control program and specific control data in the main CPU 63.

First, interrupt permission is set (step SG601). As a result, the first timer interrupt process (FIG. 133) is interrupted and activated in the first interrupt cycle, and the second timer interrupt process (FIG. 134) is interrupted and activated in the second interrupt period.

In the present embodiment, the processing at the start of supply of operating power (steps SG501 to SG521) basically prohibits the interrupts of the first timer interrupt processing (FIG. 133) and the second timer interrupt processing (FIG. 134). In the setting confirmation process (FIG. 258) and the setting value update process (FIG. 259), interruption is permitted. Therefore, in the situation where the setting confirmation process (FIG. 258) and the set value update process (FIG. 259) are not executed in the process (steps SG501 to SG521) at the start of supplying the operating power, the first timer interrupt process (FIG. 133) and the execution of the second timer interrupt process (FIG. 134) are prohibited, and the first timer interrupt process (FIG. 133) is executed in the situation where the setting confirmation process (FIG. 258) or the set value update process (FIG. 259) is being executed. ) And the execution of the second timer interrupt process (FIG. 134) are permitted. However, in the situation where the setting confirmation process (FIG. 258) or the setting value update process (FIG. 259) is being executed, the start-up processing flag is set to “1”, so the first timer interrupt process (FIG. Even if 133) is activated, among the various processes of the first timer interrupt process (FIG. 133), the processes for performing power failure monitoring, updating various counters, and fraudulent monitoring are executed, while progressing the game. The first timer interrupt process (FIG. 133) is terminated without executing the process.

After that, "1" is set to the setting confirmation display flag on condition that "1" is not set to the setting confirmation display flag provided in the work area 221 for specific control (step SG602). When the setting confirmation display flag is set to "1", an affirmative determination is made in step S9005 of the second timer interrupt processing (FIG. 134). (Step S9006) is executed. The processing contents of the setting processing for the fifth display data buffer 275 during the setting confirmation are the same as those in the 45th embodiment. As a result of the processing being performed, a display indicating that the setting value of the pachinko machine 10 is being confirmed and the current setting value of the pachinko machine 10, as shown in the explanatory view of FIG. Is displayed on the first to fourth notification display devices 201 to 204.

After that, the confirmation start command is transmitted to the sound-light side CPU 353 (step SG603). Upon receiving the confirmation start command, the sound-light side CPU 353 can recognize the image indicating that the setting confirmation process (FIG. 258) is being executed and the operation content for ending the setting confirmation process (FIG. 258). The display control device 82 is display-controlled so that the image to be displayed is displayed on the symbol display device 41. This allows the manager of the gaming hall to recognize that the current setting value of the pachinko machine 10 is being confirmed, and is necessary for ending the setting confirmation process (FIG. 258). It is possible for the manager of the game hall to recognize various operation contents. In addition to or instead of the above-mentioned notification being performed by the symbol display device 41, at least one of the display light emitting unit 53 and the speaker unit 54 may be configured. Further, it may be configured such that an external output indicating that the setting confirmation process (FIG. 258) is being executed is performed to a device outside the pachinko machine 10, such as a game hall management computer.

After that, the setting key insertion unit 68a determines whether or not the ON state is switched to the OFF state by using the setting key (step SG604). Specifically, similarly to the setting confirmation process (FIG. 155) in the forty-fifth embodiment, the reception state of the signal received from the detection sensor that detects the state of the setting key insertion portion 68a corresponds to the ON state. It is determined whether the reception state corresponding to the OFF state has been changed to the reception state corresponding to the OFF state. Therefore, not only when the setting key insertion section 68a is maintained in the ON state, but also when the setting confirmation processing (FIG. 258) is started in the situation where the setting key insertion section 68a is in the OFF state, the OFF state is changed. Even if it is maintained, a negative determination is made in step SG604. When it is not specified that the setting key insertion unit 68a has switched from the ON state to the OFF state (step SG604: NO), the process of step SG604 is repeated.

When it is specified that the setting key insertion part 68a has been switched from the ON state to the OFF state (step SG604: YES), the setting confirmation display flag in the specific control work area 221 is cleared to "0" (step SG605). As a result, a negative determination is made in step S9005 of the second timer interrupt processing (FIG. 134), so that the setting processing (step S9006) for the fifth display data buffer 275 during the setting confirmation is not executed. Therefore, on the first to fourth notification display devices 201 to 204, a display indicating that the current setting value of the pachinko machine 10 is being confirmed and a display indicating the current setting value of the pachinko machine 10 are displayed. The state to be performed is released.

After that, the interruption is prohibited (step SG606). As a result, the first timer interrupt process (see 133) and the interrupt of the second timer interrupt processing (FIG. 134) are prohibited.

After that, a return command for confirmation is transmitted to the sound-light side CPU 353 (step SG607). By receiving the return command at the time of confirmation, the sound-light side CPU 353 specifies that the process at the time of starting the supply of the operating power (steps SG501 to SG521) is completed in the main CPU 63, and at the same time supplies the operating power at this time. It is specified that the setting confirmation processing (FIG. 258) has been executed in the processing at the start (steps SG501 to SG521). Then, the processing corresponding to the reception of the confirmation return command is executed. The contents of the processing will be described later.

As described above, when the power of the pachinko machine 10 is turned on while the setting key insertion portion 68a is turned on by the setting key without pressing the reset button 68c, the supply of operating power to the main CPU 63 is started. In the situation where the main process (FIG. 257) is started and the reset button 68c is not pressed and the setting key insertion part 68a is turned ON, the game is advanced in the main process (FIG. 257). The setting confirmation process (FIG. 258) is executed in a condition before the process is executed, which is a condition before the supply of the operating power is started. As a result, it becomes possible to confirm the set value in a situation where the game is not being played.

Returning to the description of the main processing (FIG. 257), when the setting key insertion unit 68a has not been turned on using the setting key and the setting confirmation display flag is not set to "1" (step SG510 and Step SG511: NO), and the normal recovery command is transmitted to the sound-light side CPU 353 (step SG513). By receiving the normal return command, the sound-light side CPU 353 identifies that the main CPU 63 has completed the process (steps SG501 to SG521) at the time of starting the supply of the operating power, and at the time of starting the supply of the operating power this time. It is specified that the RAM clear process (FIG. 260), the setting confirmation process (FIG. 258), and the set value update process (FIG. 259) are not executed in the process (steps SG501 to SG521). Then, the processing corresponding to the reception of the normal return command is executed.

On the other hand, when it is determined that the reset button 68c has been pressed and the setting key insertion portion 68a has been determined to be ON-operated using the setting key (step SG508 and step SG514: YES), Alternatively, when it is determined in step SG507 that the setting update display flag is set to "1", the setting value update process is executed (step SG515). Not only when the reset button 68c is pressed as described above and when the setting key insertion portion 68a is turned on (that is, when the "setting change operation" is performed), the reset button 68c Even if the setting update display flag is set to "1" regardless of whether or not the pressing operation and the ON operation of the setting key insertion portion 68a are performed, the setting value update processing (FIG. 259) is executed to update the setting value. When the process at the time of power failure is executed in the situation where the process (FIG. 259) is being executed, the operation content at the time of starting the supply of the operating power thereafter is “no operation”, “RAM clear operation”, “change setting”. Regardless of whether it is an “operation” or a “setting confirmation operation”, the set value update processing (FIG. 259) is executed. As a result, it becomes possible to give priority to the execution of the setting value update processing (FIG. 259).

Here, the setting value update processing executed in step SG515 will be described. FIG. 259 is a flowchart showing the setting value update processing. Note that the processing of steps SG701 to SG713 in the setting value update processing is executed using the program for specific control and the data for specific control in the main CPU 63.

First, interrupt permission is set (step SG701). As a result, the first timer interrupt process (FIG. 133) is interrupted and activated in the first interrupt cycle, and the second timer interrupt process (FIG. 134) is interrupted and activated in the second interrupt period.

In the present embodiment, the processing at the start of supply of operating power (steps SG501 to SG521) basically prohibits the interrupts of the first timer interrupt processing (FIG. 133) and the second timer interrupt processing (FIG. 134). In the setting confirmation process (FIG. 258) and the setting value update process (FIG. 259), interruption is permitted. Therefore, in the situation where the setting confirmation process (FIG. 258) and the set value update process (FIG. 259) are not executed in the process (steps SG501 to SG521) at the start of supplying the operating power, the first timer interrupt process (FIG. 133) and the execution of the second timer interrupt process (FIG. 134) are prohibited, and the first timer interrupt process (FIG. 133) is executed in the situation where the setting confirmation process (FIG. 258) or the set value update process (FIG. 259) is being executed. ) And the execution of the second timer interrupt process (FIG. 134) are permitted. However, in the situation where the setting confirmation process (FIG. 258) or the setting value update process (FIG. 259) is being executed, the start-up processing flag is set to “1”, so the first timer interrupt process (FIG. Even if 133) is activated, among the various processes of the first timer interrupt process (FIG. 133), the processes for performing power failure monitoring, updating various counters, and fraudulent monitoring are executed, while progressing the game. The first timer interrupt process (FIG. 133) is terminated without executing the process.

After that, "1" is set in the setting update display flag on condition that "1" is not set in the setting update display flag provided in the work area 221 for specific control (step SG702). When the setting update display flag is set to "1", a positive determination is made in step S9003 of the second timer interrupt process (FIG. 134), and the setting process for the fifth display data buffer 275 during the setting update is performed. (Step S9004) is executed. The processing content of the setting processing for the fifth display data buffer 275 during the setting update is the same as that in the 45th embodiment. By executing the process, as shown in the explanatory view of FIG. 124(a), for example, a display indicating that the setting value of the pachinko machine 10 is being updated and selection as an update target of the pachinko machine 10 are made. The displayed set values are displayed on the first to fourth notification display devices 201 to 204.

After that, initial setting at the start is performed (step SG703). In the initial setting, the game stop flag provided in the work area 221 for specific control is cleared to "0". As for the game stop flag, when the power failure flag is not set to "1" because the power failure process was not properly performed at the previous power shutdown (step SG504: NO), the work area 221 for specific control and When the checksums do not match due to the change in the storage state of information since the last power-off of at least one of the stack areas 222 for specific control (step SG505: NO), or the setting reference area 341 This is a flag that is set to "1" in step SG518 of the main process (FIG. 257) when the set value corresponding to the information stored in is not in the normal range (step SG506: NO). When the game stop flag is set to "1", the processes of steps S8901 to S8905 are executed in the first timer interrupt process (FIG. 133), while the positive determination is made in step S8906 to steps S8907 to step. The process of S8920 is not executed. As a result, when the information abnormality of the main RAM 65 as described above occurs, the processing for performing the power failure monitoring, the updating of various counters and the illegality monitoring is executed, while the processing for advancing the game is executed. Will not be done. By clearing the game stop flag to "0" in the process of step SG703, the state in which the occurrence of the information abnormality of the main RAM 65 is specified is canceled when the set value update process (FIG. 259) is executed. Is possible.

After that, "1" is set in the setting update area 342 (see FIG. 154) in the specific control work area 221 (step SG704). The setting update area 342 is a storage area for storing information on the setting value being updated in the setting value updating process (FIG. 259) as in the 45th embodiment. When the numerical information of “1” is stored in the setting update area 342, the set value of the update target (selection target or change target) is “setting 1”. When the numerical information of “2” is stored in the setting update area 342, the setting value to be updated is “setting 2”. When the numerical information of “3” is stored in the setting update area 342, the setting value to be updated is “setting 3”. When the numerical information of "4" is stored in the setting update area 342, the setting value to be updated is "setting 4". When the numerical information of "5" is stored in the setting update area 342, the setting value to be updated is "setting 5". When the numerical information of “6” is stored in the setting update area 342, the setting value to be updated is “setting 6”.

By setting "1" in the setting update area 342 in step SG704, the setting value to be updated becomes "setting 1". That is, in the present embodiment, the setting value to be updated becomes “setting 1” when the setting value updating process (FIG. 259) is started regardless of the current setting value of the pachinko machine 10.

After that, the update start command is transmitted to the sound-light side CPU 353 (step SG705). Upon receiving the update start command, the sound-light side CPU 353 receives an image to show that the setting value update processing (FIG. 259) is being executed, an image for making the operation contents for changing the setting value recognizable, And the display control device 82 is display-controlled so that an image for making it possible to recognize the operation content for terminating the setting value update processing (FIG. 259) is displayed on the symbol display device 41. This allows the manager of the game hall to recognize that the setting value is being changed, and the operation content and the setting value update process necessary to change the setting value (FIG. 259). It becomes possible for the manager of the game hall to recognize the operation content necessary for ending the game. In addition to or instead of the above-mentioned notification being performed by the symbol display device 41, at least one of the display light emitting unit 53 and the speaker unit 54 may be configured. Further, a configuration may be adopted in which an external output indicating that the set value update processing (FIG. 259) is being executed is performed to a device outside the pachinko machine 10, such as a game hall management computer.

After that, it is determined whether or not the setting value information stored in the setting update area 342 is any one of "1" to "6" (step SG706). If it is not any of "1" to "6" (step SG706: NO), "1" is set in the setting update area 342 (step SG707). As a result, the setting value to be updated becomes “setting 1”.

When an affirmative determination is made in step SG706 or the processing of step SG707 is executed, it is determined whether the setting key insertion unit 68a has switched from the ON state to the OFF state using the setting key (step SG708). Specifically, it is determined whether the reception state of the signal received from the detection sensor that detects the state of the setting key insertion unit 68a has changed from the reception state corresponding to the ON state to the reception state corresponding to the OFF state. To do. Therefore, the OFF state is maintained not only when the setting key inserting section 68a is maintained in the ON state, but also when the setting value updating process is started in the situation where the setting key inserting section 68a is in the OFF state. Also in this case, a negative determination is made in step SG708.

When a negative determination is made in step SG708, the value of the setting update area 342 is incremented by 1 on the condition that the reset button 68c is pressed (step SG709: YES) (step SG710). As a result, each time the reset button 68c is pressed once, the setting value is updated by one step. When the reset button 68c is not pressed (step SG709: NO) or when the value of the setting update area 342 is incremented by 1, the process returns to step SG706, but the setting update is performed in step SG706. If it is determined that the value of the use area 342 is 7 or more, “1” is set in the setting update area 342 in step SG707. As a result, when the reset button 68c is pressed once in the situation of "setting 6", the process returns to "setting 1".

When it is specified that the setting key insertion unit 68a is switched from the ON state to the OFF state (step SG708: YES), the setting reference area 341 is overwritten with the setting value information stored in the setting updating area 342 ( Step SG711). As a result, the setting value information obtained as a result of the update in the setting value update processing this time (FIG. 259) is set in the setting reference area 341, and the setting value corresponding to the set information is the current state. It becomes the set value of the pachinko machine 10.

After that, the interruption is prohibited (step SG712). As a result, when the set value updating process (FIG. 259) is terminated and the process returns to the process (steps SG501 to SG521) at the start of supplying the operating power in the main process (FIG. 257), the first timer interrupt process (FIG. 133) and the interrupt of the second timer interrupt processing (FIG. 134) are prohibited.

After that, a RAM clearing process is executed (step SG713). In the RAM clearing process, the specific control work area 221 is excluded except for the area (that is, the setting reference area 341) in which the setting value information indicating the setting state of the pachinko machine 10 is set in the specific control work area 221. Is cleared to "0" and the initial setting is executed. In the RAM clearing process, the stack area 222 for specific control is cleared to "0" and the initial setting is executed. In the RAM clearing process, various registers of the main CPU 63 are cleared to "0" and then the initial setting is executed. In this initial setting, the same processing as the internal function register setting processing in step SF502 is executed. The process for clearing “0” and the process for initial setting are not executed for the work area 223 for non-specific control and the stack area 224 for non-specific control. Details of the RAM clear processing will be described later.

Based on not only performing the power ON operation of the pachinko machine 10 while pressing the reset button 68c as described above, but also performing the power ON operation of the pachinko machine 10 while further operating the setting key insertion portion 68a by the setting key. The set value update process (FIG. 259) is executed. Further, as described above, the setting confirmation processing (FIG. 258) is performed based on the power-on operation of the pachinko machine 10 while the setting key insertion portion 68a is turned on by the setting key without pressing the reset button 68c. To be executed. As a result, it becomes possible to make the ON operation for the setting key insertion unit 68a common as the operation for executing the setting related processing regarding the setting value. Therefore, it becomes possible for the manager of the game hall to easily understand the operation content for generating the setting-related processing.

Further, when the power of the pachinko machine 10 is turned on while the setting key insertion portion 68a is turned on by the setting key, and the pressing operation of the reset button 68c is not added, the setting confirmation process (FIG. 258) is performed. When the reset button 68c is pressed, the set value updating process (FIG. 259) is executed. As a result, it is possible to make the target process of the setting confirmation process (FIG. 258) and the setting value update process (FIG. 259) different depending on whether the reset button 68c is pressed or not. Therefore, it becomes possible for the manager of the game hall to easily understand the operation content for executing the desired processing of the setting confirmation processing (FIG. 258) and the setting value update processing (FIG. 259). Further, by making the operation contents for executing the set value update process (FIG. 259) larger than the setting confirmation process (FIG. 258), the action for making the set value update process (FIG. 259) illegal is performed. It is possible to make it difficult.

Returning to the explanation of the main processing (FIG. 257), when it is determined in step SG508 that the reset button 68c has been pressed, and the setting key insertion portion 68a has not been turned ON using the setting key. If determined (step SG514: NO), it is determined whether or not "1" is set in the game stop flag in the work area 221 for specific control (step SG516). The game stop flag is a flag that is set to "1" when "1" is not set in the power failure flag, when the checksums do not match, or when the set value is abnormal. When the game stop flag is set to "1", the processes of steps S8901 to S8905 are executed in the first timer interrupt process (FIG. 133), while the positive determination is made in step S8906 to steps S8907 to step. The process of S8920 is not executed. As a result, when the power failure flag is not set to “1” because the power failure process was not properly performed at the previous power shutdown, the work area 221 for the specific control and the stack area 222 for the specific control are If at least one of the checksums does not match due to the change in the information storage state since the last power-off, or if the set value is abnormal, power failure monitoring, updating of various counters and illegal operation While the processing for monitoring is executed, the processing for advancing the game is not executed.

When "1" is not set in the game stop flag (step SG516: NO), RAM clear processing is executed (step SG517). The contents of the RAM clearing process are the same as the contents of the RAM clearing process of step SG713 in the set value updating process (FIG. 259). That is, in step SG517 of the main process (FIG. 257) and step SG713 of the set value update process (FIG. 259), the same subroutine is called to execute the RAM clear process.

FIG. 260 is a flowchart showing the RAM clearing process executed in step SG517 of the main process (FIG. 257) and step SG713 of the set value updating process (FIG. 259). The processes of steps SG801 to SG808 in the RAM clearing process are executed using the specific control program and the specific control data in the main CPU 63.

First, in the work area 221 for specific control, a clear start address, which is a start address when executing the RAM clear process, is set as a target address (step SG801). A setting reference area 341 is set in an area corresponding to the start address of the specific control work area 221, and a clear start address is set to an address in the next order with respect to the setting reference area 341. .. As a result, the setting reference area 341 can be excluded from the execution targets of the RAM clearing process.

Then, a clear process is executed (step SG802). In the clear processing of step SG802, the area corresponding to the current target address in the work area 221 for specific control is cleared to "0", and the target address is set to the next address in the work area 221 for specific control. .. Then, the process of clearing "0" and the process of updating the target address are executed until the address of the next order becomes the target address with respect to the address of the last order in the work area 221 for specific control. As a result, the area indicating whether or not the winning/winning lottery mode is the high-probability mode is cleared to "0". The mode is a low probability mode. In addition, the game times are not being executed, the opening/closing execution mode is not being executed, and the general-purpose display unit 38a is not being variably displayed, and the general electric accessory 34a is in the closed state. It becomes a situation. Further, since the hold storage area 65a and the universal electric power reserve area 65c provided in the work area 221 for specific control are also cleared to "0", the reserved information for the special figure display section 37a is deleted and the general figure display section is deleted. The hold information for 38a is deleted. Further, the setting update display flag and the setting confirmation display flag provided in the specific control work area 221 are cleared to "0". In addition, the setting update area 342 provided in the specific control work area 221 is cleared to “0”. Further, the game stop flag provided in the work area 221 for specific control is cleared to "0".

Then, the start address of the stack area 222 for specific control is set to the target address (step SG803). After that, a clear process is executed (step SG804). In the clear processing of step SG804, the area corresponding to the current target address in the stack area 222 for specific control is cleared to “0”, and the target address is set to the next address in the stack area 222 for specific control. .. Then, the process of clearing “0” and the process of updating the target address are executed until the address in the next order becomes the target address with respect to the address in the last order in the stack area 222 for specific control.

After that, the initial setting of the main RAM 65 is executed (step SG805). Further, various registers of the main CPU 63 are cleared to "0" (step SG806), and the initial setting of the various registers is executed (step SG807). In this initial setting, the same processing as the internal function register setting processing of step SG502 in the main processing (FIG. 257) is executed.

After that, a clear completion command is transmitted to the sound-light side CPU 353 (step SG808). Upon receiving the clear completion command, the sound-light side CPU 353 identifies that the processing (steps SG501 to SG521) at the time of starting the supply of the operating power is completed in the main CPU 63, and at the time of starting the supply of the operating power this time. It is specified that the RAM clear process of step SG517 or the RAM clear process of step SG713 of the set value update process (FIG. 259) is executed in the process (steps SG501 to SG521). Then, the processing corresponding to the reception of the clear completion command is executed. The contents of the processing will be described later.

In the main process (FIG. 257), when a negative determination is made in any of step SG504, step SG505 and step SG506, that is, when the power failure flag is not set to "1", the checksums do not match, or the setting is made. If the value is abnormal, the game stop flag in the specific control work area 221 is set to "1" (step SG518). As described above, by setting the game stop flag to "1", the processes of steps S8901 to S8905 are executed in the first timer interrupt process (FIG. 133), while the positive determination is made in step S8906. The processes of steps S8907 to S8920 are not executed. As a result, when the power failure flag is not set to “1” because the power failure process was not properly performed at the previous power shutdown, the work area 221 for the specific control and the stack area 222 for the specific control are If at least one of the checksums does not match due to the change in the information storage state since the last power-off, or if the set value is abnormal, power failure monitoring, updating of various counters and illegal operation While the processing for monitoring is executed, the processing for advancing the game is not executed.

Then, it is determined whether or not the reset button 68c has been pressed (step SG519). When the reset button 68c has not been pressed (step SG519: NO), an abnormal command indicating that an abnormality has occurred with respect to the power failure flag, the checksum, or the set value at the start of supplying the operating power is transmitted to the sound-light side CPU 353. (Step SG520). Upon receiving the abnormality command, the sound-light side CPU 353 causes the display light emitting unit 53 to emit light in a manner corresponding to the information abnormality at the time of starting the supply of the operating power, and the speaker unit 54 "Please change the setting." Is output. Moreover, the character image "Please change the setting." is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are ended when the supply of operating power to the pachinko machine 10 is stopped. However, even if the supply of the operating power to the pachinko machine 10 is temporarily stopped, the above notification is given when the supply of the operating power to the pachinko machine 10 is resumed until the setting value update process (FIG. 259) is executed. It will be started again.

Then, the external output process at the time of abnormality is executed (step SG521). In the external output process at the time of abnormality, a process for externally outputting an abnormality signal to the management computer of the game hall is executed. In this case, the signal output of the abnormal signal is performed over a predetermined period (for example, 100 milliseconds). However, the present invention is not limited to this, and under the condition that the game stop flag is set to "1", the signal output of the abnormal signal is continued, and the game stop flag is cleared to "0", thereby indicating the abnormal signal. The signal output may be stopped. The abnormality signal can also be output when an abnormality different from the abnormality regarding the power failure flag, the checksum, and the set value occurs. For example, in the fraud detection process (step S8905) of the first timer interrupt process (FIG. 133), even when it is specified that a fraud of the monitoring target (illegal radio wave detection or fraudulent magnetism detection) occurs, the abnormal signal is generated It is output externally. However, the configuration is not limited to such a configuration in which an abnormality signal is also used, and a configuration in which an abnormality signal dedicated to an abnormality related to a power failure flag, checksum, or set value may be externally output may be used. It is also possible to have a configuration in which an abnormality signal corresponding to each of the abnormality regarding the check, the abnormality regarding the checksum, and the abnormality regarding the set value is externally output.

When the reset button 68c has been pressed (step SG519: YES), it is determined whether the setting key insertion unit 68a has been turned on using the setting key (step SG514). When the reset button 68c is pressed and the setting key insertion part 68a is turned on by using the setting key (step SG514 and step SG519: YES), the set value updating process is executed (step SG515). The processing content of the setting value update processing is as already described. That is, when the operating power is supplied to the main CPU 63 in the situation where the “setting change operation” is being performed, one of step SG504, step SG505, and step SG506 due to the occurrence of an abnormality in the main RAM 65. Even if a negative determination is made in step S1, the setting value update processing (FIG. 259) is executed. Thereby, it becomes possible to give priority to the change of the set value. Further, in the set value update processing (FIG. 259), the game stop flag is cleared to "0" by executing the initial setting at the start in step SG703 as already described. As a result, when the set value update process (FIG. 259) is executed, it is possible to eliminate the state in which an abnormality has occurred in the main RAM 65 after the set value update is completed.

On the other hand, when the reset button 68c is pressed but the setting key insertion portion 68a is not turned on (step SG519: YES, step SG514: NO), the game stop flag in the work area 221 for specific control is set to "1". Is set (step SG516). In the process of step SG516 after the game stop flag is set to "1" in step SG518, since the game stop flag is set to "1" as a matter of course, a positive determination is made in step SG516. In this case, an abnormal command is transmitted to the sound-light side CPU 353 in step SG520, and an abnormal signal is externally output in step SG521.

That is, when an abnormality related to the power failure flag, the checksum, and the set value occurs and a negative determination is made in any of step SG504, step SG505, and step SG506, the main CPU 63 in the state where the "RAM clear operation" is performed. The RAM clearing process (step SG517) is not executed even if the supply of operating power to the device is started. Also, when the game stop flag is set to "1" and the "RAM clear operation" is being performed and the supply of operating power to the main CPU 63 is started, the RAM clear process ( Step SG517) is not executed. As a result, even if the supply of operating power to the main CPU 63 is started while the "RAM clear operation" is being performed, the state in which the game stop flag is set to "1" can be prevented from being resolved. It will be possible. On the other hand, when the "setting change operation" is performed, the setting value update processing (FIG. 259) is executed and the setting is performed regardless of whether the game stop flag is set to "1" or not. The game stop flag is cleared to "0" in the initial setting (step SG703) at the start of the value updating process (Fig. 259). As a result, it becomes necessary to execute the set value updating process (FIG. 259) in order to cancel the state in which the game stop flag is set to "1". Therefore, when the information abnormality of the work area 221 for specific control occurs, not only the process for initializing the work area 221 for specific control, but also the resetting of the set value can be required. ..

Further, when the supply of operating power to the main CPU 63 is started in a situation where the game stop flag is set to "1", when "setting change operation" is not performed, that is, "no operation" In case of “RAM clear operation” or “setting confirmation operation”, an affirmative judgment is made in step SG509 or step SG516, so that an abnormal command is transmitted in step SG520 and abnormal in step SG521. The external output process of is executed. As a result, when the game stop flag is set to "1", the set value update process (FIG. 259) is executed irrespective of the processing results of step SG504, step SG505 and step SG506 in the subsequent main process. Every time the supply of operating power to the main CPU 63 is started, an abnormality notification in the pachinko machine 10 and an external output at the time of an abnormality to the outside of the pachinko machine 10 are performed. Therefore, it becomes possible to let the manager of the game hall recognize that the set value should be changed.

When the process of step SG512 is performed, the process of step SG513 is performed, the process of step SG515 is performed, the process of step SG517 is performed, or the process of step SG521 is performed, Information corresponding to the initial check period (specifically, 5 seconds) is set in the checking counter provided in the work area 221 (step SG522). The value set in the checking counter is decremented by 1 each time the second timer interrupt process (FIG. 134) is activated, as in the 35th embodiment. If a value greater than or equal to 1 is set in the checking counter, the process of step S9102 is executed in the normal setting process (FIG. 135) in the second timer interrupt process (FIG. 134), so that Similar to the above embodiment, the check display is continued on the first to fourth notification display devices 201 to 204.

According to the above configuration, when the supply of the operating power to the main CPU 63 is started, the residual processing is performed after the processing at the start of the supply of the operating power (steps SG501 to SG521) is completed in the main CPU 63. The initial check period is started before (steps SG524 to SG527) are started. Accordingly, since it is not necessary to control the initial check period in the situation where the process at the start of supplying the operating power (steps SG501 to SG521) is executed, the process at the start of supplying the operating power (steps SG501 to step SG501). It is possible to reduce the processing load in the situation where SG521) is being executed.

Further, the setting confirmation process (FIG. 258) and the setting value update process (FIG. 259) are executed as the process (steps SG501 to SG521) at the start of supplying the operating power, while the initial check period is the operating power. Is started after the processing (step SG501 to step SG521) at the start of supply of No. is completed. Accordingly, even if the check display is performed on the first to fourth notification display devices 201 to 204 during the initial check period, the set values are displayed using the first to fourth notification display devices 201 to 204. It becomes possible not to affect.

Then, the start-up processing flag in the work area 221 for specific control is cleared to "0" (step SG523). When the first timer interrupt process (FIG. 133) is started by clearing the start-up processing flag “0”, a negative determination is made in step S8906, and thus not only the processes of steps S8901 to S8905 The processing of steps S8907 to S8920 will be executed, and the state where the processing for advancing the game is not executed is released. In step SG523, the power failure flag in the work area 221 for specific control is also cleared to "0".

After that, the procedure proceeds to the residual processing of steps SG524 to SG527. In other words, the main CPU 63 is configured to periodically execute the first timer interrupt process (FIG. 133) and the second timer interrupt process (FIG. 134), but between the one timer interrupt process and the next timer interrupt process. There will be some residual time. This remaining time will vary depending on the processing completion time of each timer interrupt processing, but the remaining processing of steps SG524 to SG527 is repeatedly executed using this irregular time. In this respect, it can be said that the residual processing of steps SG524 to SG527 is non-periodic processing that is executed non-periodically. In steps SG524 to SG527, the same processing as steps S113 to S116 of the main processing (FIG. 9) in the first embodiment is executed.

Next, the open/close monitoring process executed by the main CPU 63 will be described with reference to the flowchart in FIG. The open/close monitoring process is executed as a part of the input state monitoring process (step S8912) in the first timer interrupt process (FIG. 133). Note that the processes of steps SG901 to SG908 in the opening/closing monitoring process are executed using the program for specific control and the data for specific control in the main CPU 63.

First, it is determined whether or not the opening operation of the gaming machine body 12 has been performed (step SG901). Also in this embodiment, a main body opening sensor 96 is provided on the front surface of the back pack unit 15 as in the first embodiment (see FIG. 2). In this case, in the present embodiment, the detection result of the main body opening sensor 96 is input to the main CPU 63 instead of the payout CPU 92. Then, when the gaming machine main body 12 is closed with respect to the outer frame 11, the main body opening sensor 96 transmits a closing detection signal to the main CPU 63, and the gaming machine main body 12 is in the open state with respect to the outer frame 11. In this case, the main body open sensor 96 sends an open detection signal to the main CPU 63. The main CPU 63 specifies that the gaming machine main body 12 is in the closed state when receiving the closing detection signal from the main body opening sensor 96, and determines when the opening detection signal is received from the main body opening sensor 96. It specifies that the main body 12 is in the open state. In step SG901, when it is specified that the closing detection signal is received from the main body opening sensor 96 in the opening/closing monitoring processing (FIG. 261) at the previous processing time, the opening/closing monitoring processing at this processing time (FIG. At 261), it is determined whether or not the open detection signal is received from the main body open sensor 96.

When it is determined that the opening operation of the gaming machine main body 12 has been performed (step SG901: YES), a main body opening command is transmitted to the sound-light side CPU 353 (step SG902). Upon receiving the main body opening command, the sound-light side CPU 353 executes the corresponding process. The contents of the processing will be described later.

In the opening/closing monitoring process, it is further determined whether or not the closing operation of the gaming machine body 12 has been performed (step SG903). In step SG903, when it is specified in the opening/closing monitoring processing (FIG. 261) in the previous processing time that the opening detection signal is received from the main body opening sensor 96, the opening/closing monitoring processing in the current processing time ( In FIG. 261), it is determined whether or not the closing detection signal is received from the main body opening sensor 96.

When it is determined that the closing operation of the gaming machine main body 12 is performed (step SG903: YES), a main body closing command is transmitted to the sound-light side CPU 353 (step SG904). Upon receiving the main body closing command, the sound-light side CPU 353 executes the corresponding process. The contents of the processing will be described later.

In the open/close monitoring process, it is further determined whether or not the opening operation of the front door frame 14 has been performed (step SG905). Also in this embodiment, a front door opening sensor 95 is provided on the front surface of the inner frame 13 as in the first embodiment (see FIG. 2). In this case, in the present embodiment, the detection result of the front door opening sensor 95 is input to the main CPU 63 instead of the payout CPU 92. Then, when the front door frame 14 is closed with respect to the inner frame 13, the front door open sensor 95 transmits a close detection signal to the main CPU 63, and the front door frame 14 is opened with respect to the inner frame 13. In the case of, the front door opening sensor 95 sends an opening detection signal to the main CPU 63. The main CPU 63 specifies that the front door frame 14 is in the closed state when receiving the closing detection signal from the front door opening sensor 95, and when receiving the opening detection signal from the front door opening sensor 95. The front door frame 14 is specified to be in the open state. In step SG905, when it is specified that the closing detection signal is received from the front door opening sensor 95 in the opening/closing monitoring processing in the previous processing time (FIG. 261), the opening/closing monitoring processing in this processing time ( In FIG. 261), it is determined whether or not an opening detection signal is received from the front door opening sensor 95.

When it is determined that the opening operation of the front door frame 14 is performed (step SG905: YES), the front door opening command is transmitted to the sound-light side CPU 353 (step SG906). Upon receiving the front door opening command, the sound-light side CPU 353 executes the corresponding process. The contents of the processing will be described later.

In the opening/closing monitoring process, it is further determined whether or not the closing operation of the front door frame 14 has been performed (step SG907). In step SG907, when it is specified that the opening detection signal is received from the front door opening sensor 95 in the opening/closing monitoring processing (FIG. 261) in the previous processing time, the opening/closing monitoring processing in the current processing time is performed. At (FIG. 261), it is determined whether or not the closing detection signal is received from the front door opening sensor 95.

When it is determined that the closing operation of the front door frame 14 is performed (step SG907: YES), the front door closing command is transmitted to the sound-light side CPU 353 (step SG908). Upon receiving the front door closing command, the sound-light side CPU 353 executes the corresponding process. The contents of the processing will be described later.

Next, the processing executed by the sound emission control device 81 will be described. Prior to the description of the process, the electrical configuration of the sound emission control device 81 will be described with reference to the explanatory diagram of FIG. 262.

The voice emission control device 81 includes a voice emission control board 351 as in the forty-ninth embodiment. The sound emission side MPU 352 is mounted on the sound emission control board 351. The sound-light side MPU 352 includes a sound-light side ROM 354 and a sound-light side RAM 355 in addition to the sound-light side CPU 353 which is an arithmetic processing unit including a control unit and a calculation unit. In addition to the above-described elements, the sound/light side MPU 352 has an interrupt circuit, a timer circuit, a data input/output circuit, various counter circuits as a random number generator, and the like built therein.

The sound-light side ROM 354 is a memory such as a NOR flash memory and a NAND flash memory that does not require external power supply for storage, and is used as a read-only memory. The sound-light side ROM 354 stores various control programs executed by the sound-light side CPU 353 and fixed value data.

The sound-light side RAM 355 is a memory (that is, a volatile storage means) such as an SRAM and a DRAM that needs to be supplied with electric power from the outside to retain the storage, and is used for both reading and writing. The sound-light side RAM 355 is capable of random access and has a shorter read time than the sound-light side ROM 354 when compared with the same data capacity. The sound-light side RAM 355 temporarily stores various data and the like for the execution of the control program stored in the sound-light side ROM 354.

Although the RTC 356 and the RTC memory 357 are provided on the audio emission control board 351 in the forty-ninth embodiment, the RTC 356 and the RTC memory 357 are not provided on the audio emission control board 351 in the present embodiment. ..

Here, as described above, the main CPU 63 sends to the sound light side CPU 353 the return command and the clear completion command at the time of confirmation in the processing (step SG501 to step SG521) at the time of starting the supply of the operating power in the main processing (FIG. 257). In addition to the transmission, the main body opening command, the main body closing command, the front door opening command and the front door closing command can be transmitted to the sound light side CPU 353 in the opening/closing monitoring process (FIG. 261). When any of these commands is received, the sound-light side CPU 353 executes a process for causing the display light emitting unit 53 and the speaker unit 54 to execute the notification corresponding to the received command. When executing these notifications, various notification tables 521 to 526 stored in advance in the sound-light side ROM 354 are used.

As the various notification tables 521 to 526, when the confirmation return command is received from the main CPU 63, the post-confirmation notification table 521 referred to for executing the corresponding notification and the clear completion command are transmitted to the main CPU 63. The post-clearing notification table 522 referred to for executing the corresponding notification when received from the main body, and the main body referred to for executing the corresponding notification when the main body release command is received from the main CPU 63. An opening notification table 523, a main body closing notification table 524 that is referred to when a main body closing command is received from the main CPU 63, and the front door opening command is received from the main CPU 63. The front door open notification table 525 referred to in order to execute the corresponding notification, and the front door referred to in order to execute the corresponding notification when the front door closing command is received from the main CPU 63. A closure notification table 526 exists.

In these various notification tables 521 to 526, the light emission control data for controlling the light emission of the display light emitting unit 53 in a predetermined manner and the speaker unit 54 are specified in correspondence with each update timing of the notification period. The sound output control data for controlling the sound output in the mode is set. The data structure of the various notification tables 521 to 526 will be described by taking the post-confirmation notification table 521 as an example. FIG. 263 is an explanatory diagram for explaining the contents of the post-confirmation notification table 521.

As shown in FIG. 263, a plurality of pointer information is set in the post-confirmation notification table 521 in correspondence with each update timing of the notification content in the notification period. Further, a combination of the light emission control data and the sound output control data is set corresponding to each of the plurality of pointer information. A plurality of pieces of pointer information are arranged as numerical information of serial numbers, and each time the preset update period of 40 milliseconds elapses, the pointer information of the reference target is updated to the pointer information of the next order. Then, the emission control of the display emission section 53 is performed using the emission control data set in correspondence with the updated pointer information of the reference target, and the speaker section 54 is utilized using the sound output control data. Sound output control is performed. The update cycle is not limited to 40 milliseconds and is arbitrary.

When light emission control of the display light emitting unit 53 and sound output control of the speaker unit 54 are performed using the post-confirmation notification table 521, first, the light emission control data (corresponding to the pointer information of “0” ( X(0)) is used to control the light emission of the display light emitting unit 53, and the sound output control data (Y(0)) set corresponding to the pointer information of “0” is used. The sound output control of the speaker unit 54 is performed. As a result, the post-confirmation notification indicating that the setting confirmation process (FIG. 258) has been executed is started.

After that, each time the notification content update cycle of 40 milliseconds elapses, the pointer information of the reference target is updated to the pointer information in the next order, and is set in correspondence with the pointer information that is the new reference target. The light emission control data is used to control the light emission of the display light emitting unit 53, and the sound output control data is used to control the sound output of the speaker unit 54. For example, in the situation where the pointer information of “0” is the reference target, the reference target is updated to the pointer information of “1” when the update cycle of 40 milliseconds elapses, and corresponds to the pointer information of the “1”. The light emission control of the display light emitting unit 53 is performed by using the light emission control data (X(1)) that is set to be set, and the sound output control that is set corresponding to the pointer information of "1" is performed. The sound output control of the speaker unit 54 is performed using the use data (Y(1)). Also, in the situation where the pointer information of "1" is the reference target, the reference target is updated to the pointer information of "2" by the update cycle of 40 milliseconds, and the pointer information of the "2" is corresponded. The light emission control of the display light emitting unit 53 is performed by using the light emission control data (X(2)) that is set to be set, and the sound output control that is set in association with the pointer information of “2” is set. The sound output control of the speaker unit 54 is performed using the use data (Y(2)). Then, the light emission control of the display light emitting unit 53 is performed using the light emission control data (X(k)) that is set in the post-confirmation notification table 521 in correspondence with the pointer information of the last "k". When the sound output control of the speaker unit 54 is performed using the sound output control data (Y(k)), the execution control of the notification using the post-confirmation notification table 521 is ended, and the confirmation is performed. The post notification is ended.

That is, when the post-confirmation notification table 521 is to be used, the post-confirmation notification table 521 is used until the last-order pointer information set in the post-confirmation notification table 521 becomes the reference target. Maintained as a target. Although the details will be described later, the post-confirmation notification is set to have a higher execution priority than other notifications that can be executed at the same time. Therefore, when the post-confirmation notification table 521 is to be used, the post-confirmation notification is continued until the notification period set corresponding to the post-confirmation notification table 521 elapses.

Regarding the post-clearing notification table 522, the main body opening notification table 523, the main body closing notification table 524, the front door opening notification table 525, and the front door closing notification table 526, the emission control data and the sound output control data are also included. Although the contents are different, the basic data structure is the same as that of the post-confirmation notification table 521 shown in FIG. 263. That is, in each of the various notification tables 521 to 526, a plurality of pointer information is set, and a combination of the light emission control data and the sound output control data is set corresponding to each pointer information. Further, the update cycle of the pointer information is the same in any of the notification tables 521 to 526, but the present invention is not limited to this, and the pointer information is updated according to the type of the notification tables 521 to 526. It may be configured such that the cycles are different. The contents of the light emission control data and the sound output control data are different in each of the various notification tables 521 to 526. Therefore, the post-confirmation notification executed using the post-confirmation notification table 521, the post-clearing notification executed using the post-clearing notification table 522, and the main body executed using the main body open notification table 523 A main body closing notification executed by using the opening notification, the main body closing notification table 524, a front door opening notification executed by using the front door opening notification table 525, and a front door closing notification table 526 are used. The contents of the front door closing notification that are executed as described above are different from each other. Therefore, by checking the light emission content of the display light emitting unit 53 and the sound output content from the speaker unit 54, it becomes possible for the manager of the game hall to know which type of notification is being executed.

When the post-confirmation notification table 521 is used as described above, the post-confirmation notification table 521 is used until the last-order pointer information set in the post-confirmation notification table 521 becomes the reference target. The post-confirmation notification table 521 is released from the usage target when the notification execution control corresponding to the last-order pointer information is completed while being maintained as the target. In this way, the notification table that is maintained as the usage target until the last-order pointer information becomes the reference target and is excluded from the usage target when the execution control of the notification corresponding to the last-order pointer information is completed is In addition to the post-confirmation notification table 521, there are a post-clearing notification table 522, a main body closing notification table 524, and a front door closing notification table 526.

On the other hand, when the main body opening notification table 523 and the front door opening notification table 525 are used, even if the pointer information in the last order set in the notification tables 523 and 525 is used as a reference target. When the predetermined use cancellation condition is not satisfied, the reference target is returned to the pointer information in the first order, so that the notification tables 523 and 525 are maintained as the use target. Further, when these notification tables 523 and 525 are targets for use, no matter which pointer information is the reference target, when the predetermined use cancellation condition is satisfied, the pointers are canceled as targets for use. For details of the predetermined use cancellation condition, when the main body opening notification table 523 is set as a usage target, the predetermined use cancellation condition is satisfied when the gaming machine main body 12 is changed from the open state to the closed state. As a result, the main body opening notification table 523 is released from the usage target. Further, when the front door opening notification table 525 is set to be used, when the front door frame 14 is changed from the open state to the closed state, it is considered that a predetermined use cancellation condition is satisfied. The table 525 is released from the usage target.

The various notification tables 521 to 526 are set as usage targets by being read out to various execution areas 531 to 533 provided in the sound/light side RAM 355. As various execution areas 531 to 533, a first execution area 531, a second execution area 532, and a third execution area 533 are provided. Although each of these various execution areas 531 to 533 has a storage capacity capable of reading one type of notification tables 521 to 526, it is impossible to read a plurality of types of notification tables 521 to 526 simultaneously. It has a storage capacity.

In the various execution areas 531 to 533, priorities are set in advance for control execution targets. Specifically, the first execution area 531 is set to the highest priority, the second execution area 532 is set to the second highest priority, and the third execution area 533 is set to the lowest priority. It is set. When the notification table to be used is set in each of the first execution area 531, the second execution area 532, and the third execution area 533, the pointer information is updated at the first to third execution areas. Although the pointer information to be referred to is updated to the pointer information in the next order in the notification table set in each of 531 to 533, the light emission control data and the sound output control data are stored in the first execution area 531. The information is read from the set notification table and is not read from the notification table set in each of the second execution area 532 and the third execution area 533. Further, when the notification table to be used is set in each of the second execution area 532 and the third execution area 533, the pointer information is updated at the second and third execution areas 532 and 533. Although the pointer information to be referred to is updated to the pointer information in the next order in the notification table set for each, the light emission control data and the sound output control data are set in the second execution area 532. It is read from the notification table and is not read from the notification table set in the third execution area 533. Further, when the notification table to be used is set only in the third execution area 533, it becomes a reference target in the notification table set in the third execution area 533 due to the update timing of the pointer information. The pointer information is updated to the pointer information in the next order, and the light emission control data and the sound output control data are read from the notification table set in the third execution area 533.

Since the first to third execution areas 531 to 533 are provided as described above, it is possible to simultaneously set a plurality of notification tables as usage targets, and the priority of the plurality of notification tables is set. It becomes possible to execute the notification corresponding to the high notification table.

Further, even when the notification corresponding to the notification table with the high priority is being executed, the pointer information of the reference target is not updated at the update timing for the notification table on the side with the low priority. Will be updated. Then, when the notification corresponding to the notification table with a high priority is finished, and the notification table on the side with a low priority is still set as the usage target, the notification on the side with a low priority is performed. The light emission control data and the sound output control data corresponding to the current pointer information of the reference target are read out from the operation table, and the light emission control of the display light emitting unit 53 and the sound output control of the speaker unit 54 are performed. As a result, it becomes possible to execute the notification corresponding to the notification table on the side with the low priority at the timing when the notification corresponding to the notification table with the high priority ends. After the elapse of the period from the execution of the notification table on the side with the low priority to the end of the notification corresponding to the notification table with the high priority in the execution period of the notification table Since the notification corresponding to the notification table on the side of low priority is executed for the remaining period of the notification, the notification on the side of low priority is followed by the notification corresponding to the notification table of high priority. Even when the notifications corresponding to the usage table are executed, it is possible to prevent the total period during which the notifications are executed from becoming excessively long.

In each of the various notification tables 521 to 526, the types of execution areas 531 to 533 to be read are predetermined. FIG. 264 is an explanatory diagram for explaining the relationship between the various notification tables 521 to 526 and the types of execution areas 531 to 533 to be read.

As shown in FIG. 264, the post-confirmation notification table 521 and the post-clear notification table 522 are read into the first execution area 531 having the highest priority. In this case, the post-confirmation notification table 521 is used when the main CPU 63 executes the setting confirmation processing (FIG. 258), and the post-clear notification table 522 is RAM clear processing (FIG. If 260) is executed, it will be used. Both the setting confirmation processing (FIG. 258) and the RAM clear processing (FIG. 260) are not executed in one main processing (FIG. 257). When the supply of operating power to the sound emission control device 81 is stopped, the information stored in the sound-light side RAM 355 is erased. Therefore, when one of the post-confirmation notification table 521 and the post-clear notification table 522 is set to the first execution area 531, the other is not set to the first execution area 531.

The main body opening notification table 523 and the front door opening notification table 525 are read to the second execution area 532 having the second highest priority. In this case, the main body open notification table 523 is used when the gaming machine main body 12 changes from the closed state to the open state, and the front door open notification table 525 changes the front door frame 14 from the closed state to the open state. In some cases, it will be used. Therefore, when both the gaming machine main body 12 and the front door frame 14 are in the open state, both the main body opening notification table 523 and the front door opening notification table 525 are read targets to the second execution area 532. However, in this case, the release notification tables 523 and 525, which have been read at a later timing, are read to the second execution area 532. This makes it possible to prevent a plurality of types of open notification tables 523 and 525 from being set in the second execution area 532 at the same time. Even when only one of the opening notification tables 523 and 525 is set in this way, the gaming machine main body 12 is opened when the main body opening notification table 523 is used. When the front door opening notification table 525 is used, the front door opening notification indicating that the front door frame 14 is in the open state is executed. Even if the open notification tables 523 and 525 are set, it is possible to notify the manager of the game hall that the opening/closing body which is basically in the closed state is in the open state.

The main body closing notification table 524 and the front door closing notification table 526 are read to the third execution area 533 having the lowest priority. In this case, the main body closing notification table 524 is used when the gaming machine main body 12 changes from the open state to the closed state, and the front door closing notification table 526 changes from the open state to the closed state of the front door frame 14. In some cases, it will be used. Therefore, when both the gaming machine main body 12 and the front door frame 14 are changed from the open state to the closed state, both the main body closing notification table 524 and the front door closing notification table 526 move to the third execution area 533. Although it becomes a read target, in this case, the closing notification tables 524 and 526, which are read targets at a later timing, are read to the third execution area 533. This makes it possible to prevent the plurality of types of closing notification tables 524 and 526 from being set in the third execution area 533 at the same time. Even if only one of the closing notification tables 524 and 526 is set in this way, when the main body closing notification table 524 is used, the gaming machine main body 12 is closed. When the front door closing notification table 526 is used, the front door closing notification indicating that the front door frame 14 is in the closed state is executed. Even if the closing notification tables 524 and 526 are set, it is possible to notify the manager of the game hall that the opening/closing body that is basically in the closed state has changed from the open state to the closed state.

Here, as described above, the post-confirmation notification table 521, the post-clearing notification table 522, the main body closing notification table 524, and the front door closing notification table 526 are used until the pointer information in the last order becomes the reference target. When the notification execution control corresponding to the pointer information in the last order is completed and is maintained as a target, it is excluded from the usage target. That is, the period in which these notification tables 521, 522, 524, 526 are used is a fixed period. The fixed period differs depending on the types of the notification tables 521, 522, 524, 526. Specifically, as shown in FIG. 264, the after-confirmation notification table 521 and the after-clear notification table 522 are set with a fixed period of 30 seconds, which is the first fixed period (specific related period, first notification period). The main body closing notification table 524 and the front door closing notification table 526 have a fixed second period of 33 seconds which is a second fixed period (predetermined target related period, second notification period) longer than the first fixed period. It is set. It should be noted that the main body opening notification table 523 and the front door opening notification table 525 have no predetermined period to be used, and the main body opening notification table 523 is in the closed state after the gaming machine main body 12 is in the open state. The front door opening notification table 525 is used until the front door frame 14 is opened and then closed.

Next, the relationship between the post-confirmation notification and the main body closing notification, and the relationship between the post-clearing notification and the main body closing notification will be described with reference to the time chart of FIG. 265. 265(a) shows a period during which the gaming machine main body 12 is in an open state, FIG. 265(b) shows a period during which the setting confirmation process (FIG. 258) is being executed, and FIG. 265(c) shows 265 shows the period during which the set value update processing (FIG. 259) is being executed, and FIG. 265(d) shows the period during which the post-confirmation notification table 521 or the post-clear notification table 522 is set in the first execution area 531. 265(e) shows a period in which the main body closing notification table 524 is set in the third execution area 533, FIG. 265(f) shows a period in which the post-confirmation notification is executed, and FIG. ) Indicates a period during which the post-clearing notification is executed, and FIG. 265(h) indicates a period during which the main body closing notification is executed.

First, a case where the setting confirmation process (FIG. 258) is executed will be described.

At the timing of t1, as shown in FIG. 265(a), the gaming machine main body 12 is opened so that the setting key insertion portion 68a is exposed in front of the pachinko machine 10. Then, when the power of the pachinko machine 10 is turned on while the exposed setting key insertion portion 68a is turned on by the setting key, the main CPU 63 starts the main processing (FIG. 257). , T2, the setting confirmation process (FIG. 258) is started as shown in FIG. 265(b). It should be noted that the main body opening notification for notifying that the gaming machine main body 12 is in the open state is specified by the opening/closing monitoring process (FIG. 261) in the main CPU 63 that the gaming machine main body 12 is changed from the closed state to the open state. Since it is executed based on this, even if the supply of the operating power is started while the gaming machine main body 12 is in the open state, the main body opening notification is not executed. However, the present invention is not limited to this, and the main body opening notification may be executed even in this situation.

In the situation where the setting confirmation process (FIG. 258) is being executed, the first to fourth notification display devices 201 to 204 which are visible from the front of the pachinko machine 10 by opening the gaming machine main body 12 The current setting value is displayed at. Then, at the timing of t3, the setting confirmation process (FIG. 258) ends as shown in FIG. 265(b). In this case, the main CPU 63 sends a return command for confirmation to the sound/light side CPU 353, so that the post-confirmation notification table 521 is output from the sound/light side ROM 354 at the timing t3 as shown in FIG. 265(d). It is read and written in the first execution area 531 of the sound-light side RAM 355. As a result, at the timing of t3, the post-confirmation notification is started by the display light emitting unit 53 and the speaker unit 54 as shown in FIG. 265(f). By confirming the post-confirmation notification, the manager of the gaming hall can grasp the situation after the confirmation of the set value.

After that, at the timing of t4, the gaming machine main body 12 is changed from the open state to the closed state as shown in FIG. 265(a). In this case, the main body close command is transmitted from the main CPU 63 to the sound/light side CPU 353, and the main body close notification table 524 is read from the sound/light side ROM 354 at the timing t4 as shown in FIG. 265(e). It is written in the third execution area 533 of the sound-light side RAM 355. However, at the timing of t4, since the post-confirmation notification table 521 is still set in the first execution area 531 having a high notification execution priority as shown in FIG. 265(d), it is shown in FIG. 265(f). After the confirmation, the notification is continued, and the main body closing notification is not started as shown in FIG. 265(h). On the other hand, even if the post-confirmation notification table 521 is set in the first execution area 531 having a high notification execution priority, the pointer information of the reference target in the main body closing notification table 524 set in the third execution area 533 is set. Is updated each time the update timing is reached.

After that, at the timing of t5, 30 seconds, which is the notification period of the notification after confirmation, elapses from the timing of t3. Therefore, at the timing of t5, the post-confirmation notification table 521 is deleted from the first execution area 531 as shown in FIG. 265(d), and accordingly, the post-confirmation notification is transmitted as shown in FIG. 265(f). Will be terminated. Further, at the timing of t5, since the notification period of the body closing notification of 33 seconds has not elapsed from the timing of t4, the body closing notification table 524 is displayed in the third execution area 533 as shown in FIG. 265(e). The set state is maintained. Therefore, at the timing of t5, the body closing notification is started as shown in FIG. 265(h).

The actual notification period of the main body closing notification is a period (33 seconds) of the main body closing notification defined by the main body closing notification table 524 from the execution period of the notification by the execution of the post-confirmation notification ( The remaining period is obtained by subtracting the period from timing t4 to timing t5). The update of the pointer information of the reference target in the main body closing notification table 524 set in the third execution area 533 is performed every time the update timing is reached even in the period from the timing t4 to the timing t5. Therefore, by starting the execution control of the main body closing notification from the pointer information that is the reference target at the timing of t5, the actual notification period of the main body closing notification becomes the above remaining period.

At the timing of t6, 33 seconds, which is the notification period of the body closing notification, elapses from the timing of t4. Therefore, at the timing of t6, the main body closing notification table 524 is erased from the third execution area 533 as shown in FIG. 265(e), and accordingly, the main body closing notification is given as shown in FIG. 265(h). Will be terminated.

Here, when the setting confirmation process (FIG. 258) is executed, the gaming machine main body 12 is changed from the open state to the closed state after the setting confirmation process (FIG. 258) is completed. Therefore, the post-confirmation notification table 521 is set in the first execution area 531 and then the main body closing notification table 524 is set in the third execution area 533. Therefore, an event that the post-confirmation notification is started immediately after the main body closing notification is started does not occur.

Further, the notification period defined in the main body closing notification table 524, which has the lower notification execution priority, is set in the after-confirmation notification table 521, which has the higher notification execution priority. It is longer than the notification period. Then, as described above, the post-confirmation notification table 521 is set in the first execution area 531 and then the main body closing notification table 524 is set in the third execution area 533. This makes it possible to execute the main body closing notification after the post-confirmation notification is completed.

In addition, when the main body closing notification is executed after the post-confirmation notification is executed, the actual execution period of the main body closing notification is the main body closing notification notification period (33 seconds) defined by the main body closing notification table 524. Is the remaining period after subtracting the period (timing from timing t4 to timing t5) in which the notification is suspended by the notification after confirmation. This makes it possible to prevent the total notification period of the post-confirmation notification and the main body closure notification from becoming excessively long when the main body closure notification is subsequently executed after completion of the post-confirmation notification.

Next, a case where the set value update processing (FIG. 259) is executed will be described.

At the timing of t7, as shown in FIG. 265(a), the gaming machine main body 12 is opened so that the setting key insertion portion 68a is exposed in front of the pachinko machine 10. Then, when the power of the pachinko machine 10 is turned on while the exposed setting key insertion portion 68a is turned on by the setting key and the reset button 68c is pressed, the main CPU 63 performs the main processing. (FIG. 257) is started, and at the timing of t8, the set value updating process (FIG. 259) is started as shown in FIG. 265(c). It should be noted that the main body opening notification for notifying that the gaming machine main body 12 is in the open state is specified by the opening/closing monitoring process (FIG. 261) in the main CPU 63 that the gaming machine main body 12 is changed from the closed state to the open state. Since it is executed based on this, even if the supply of the operating power is started while the gaming machine main body 12 is in the open state, the main body opening notification is not executed.

In the situation where the set value updating process (FIG. 259) is being executed, the first to fourth notification display devices 201 to 204 which are visible from the front of the pachinko machine 10 by opening the gaming machine main body 12 The set value being updated is displayed at. Then, at the timing of t9, the set value updating process (FIG. 259) is finished as shown in FIG. 265(c). In this case, the main CPU 63 sends a clear completion command to the sound-light side CPU 353, so that the post-clearing notification table 522 is read from the sound-light side ROM 354 at the timing t9 as shown in FIG. 265(d). It is written in the first execution area 531 of the sound-light side RAM 355. As a result, at the timing of t9, the post-clearing notification is started by the display light emitting unit 53 and the speaker unit 54 as shown in FIG. 265(g). The manager of the game hall confirms the post-clearing notification, so that the situation after the setting value updating process (FIG. 259) has been performed or the clearing process of the main RAM 65 without executing the setting value updating process (FIG. 259) It is possible to understand the situation after the operation.

Then, at a timing of t10, the gaming machine main body 12 is changed from the open state to the closed state as shown in FIG. 265(a). In this case, when the main body closing command is transmitted from the main CPU 63 to the sound/light side CPU 353, the main body closing notification table 524 is read from the sound/light side ROM 354 at the timing t10 as shown in FIG. 265(e). It is written in the third execution area 533 of the sound-light side RAM 355. However, at the timing of t10, since the post-clearing notification table 522 is still set in the first execution area 531 having a high notification execution priority as shown in FIG. 265(d), it is shown in FIG. 265(g). After clearing, the notification of the main body is not started as shown in FIG. 265(h). On the other hand, even if the post-clearing notification table 522 is set in the first execution area 531 having a high notification execution priority, the pointer information of the reference target in the main body closing notification table 524 set in the third execution area 533 is set. Is updated each time the update timing comes.

After that, at the timing of t11, 30 seconds, which is the notification period of the notification after clear, elapses from the timing of t9. Therefore, at the timing of t11, the post-clear notification table 522 is deleted from the first execution area 531 as shown in FIG. 265(d), and accordingly, the post-clear notification is issued as shown in FIG. 265(g). Will be terminated. Further, at the timing of t11, since the notification period of the main body closing notification of 33 seconds has not elapsed from the timing of t10, the main body closing notification table 524 is displayed in the third execution area 533 as shown in FIG. 265(e). The set state is maintained. Therefore, at the timing of t11, the body closing notification is started as shown in FIG. 265(h).

The actual notification period of the main body closing notification is a period (33 seconds) of the main body closing notification determined by the main body closing notification table 524 from the notification period of the main body closing notification by the execution of the post-clearing notification ( The remaining period is obtained by subtracting the period from timing t10 to timing t11. The update of the pointer information of the reference target in the main body closing notification table 524 set in the third execution area 533 is performed every time the update timing is reached even in the period from timing t10 to timing t11. Therefore, by starting the execution control of the main body closing notification from the pointer information which is the reference target at the timing of t11, the actual notification period of the main body closing notification becomes the above remaining period.

At the timing of t12, 33 seconds, which is the notification period of the main body closing notification, elapses from the timing of t10. Therefore, at the timing of t12, the main body closing notification table 524 is deleted from the third execution area 533 as shown in FIG. 265(e), and the main body closing notification is given as shown in FIG. 265(h) accordingly. Will be terminated.

Here, when the set value update process (FIG. 259) is executed, the gaming machine main body 12 is changed from the open state to the closed state after the set value update process (FIG. 259) is completed. Therefore, after the clearing notification table 522 is set in the first execution area 531, the main body closing notification table 524 is set in the third execution area 533. Therefore, the event that the post-clearing notification is started immediately after the main body closing notification is started does not occur.

In addition, the notification period defined in the main body closing notification table 524, which has the lower notification execution priority, is set in the post-clearing notification table 522, which has the higher notification execution priority. It is longer than the notification period. As described above, after the clearing notification table 522 is set in the first execution area 531, the main body closing notification table 524 is set in the third execution area 533. As a result, it becomes possible to execute the main body closing notification after the completion of the post-clearing notification.

Further, when the main body closing notification is executed after the post-clearing notification is executed, the actual execution period of the main body closing notification is the main body closing notification notification period (33 seconds) defined by the main body closing notification table 524. Is the remaining period after subtracting the period (timing from t10 to timing t11) in which the execution of the notification is suspended by the execution of the notification after clearing. This makes it possible to prevent the total notification period of the post-clearing notification and the main body closing notification from becoming excessively long when the main body closing notification is continuously executed after completion of the post-clearing notification.

Next, the effect control process executed by the sound-light side CPU 353 will be described with reference to the flowchart of FIG. 266. The effect control process is repeatedly executed in a relatively short cycle (for example, 5 milliseconds) when the supply of operating power to the sound-light side CPU 353 is started.

When the confirmation start command is received from the main CPU 63 (step SH101: YES), the confirmation notification setting process is executed (step SH102). As described above, the confirmation start command is transmitted to the sound/light side CPU 353 when the setting confirmation process (FIG. 258) is started by the main CPU 63. In the confirmation notification setting process, an image showing that the setting confirmation process (FIG. 258) is being executed and an image for making it possible to recognize the operation content for ending the setting confirmation process (FIG. 258) are displayed. The display control device 82 controls the display so that it is displayed on the symbol display device 41. This allows the manager of the gaming hall to recognize that the current setting value of the pachinko machine 10 is being confirmed, and is necessary for ending the setting confirmation process (FIG. 258). It is possible for the manager of the game hall to recognize various operation contents. In addition to or instead of the above-mentioned notification being performed by the symbol display device 41, at least one of the display light emitting unit 53 and the speaker unit 54 may be configured.

When the update start command is received from the main CPU 63 (step SH103: YES), the update notification setting process is executed (step SH104). As described above, the update start command is transmitted to the sound/light side CPU 353 when the setting value update processing (FIG. 259) is started by the main CPU 63. In the update notification setting process, an image showing that the set value update process (FIG. 259) is being executed, an image for making the operation content for changing the set value recognizable, and the set value update process ( The display control device 82 is controlled so that an image for making it possible to recognize the operation content for ending (FIG. 259) is displayed on the symbol display device 41. This allows the manager of the game hall to recognize that the setting value is being changed, and the operation content and the setting value update process necessary to change the setting value (FIG. 259). It becomes possible for the manager of the game hall to recognize the operation content necessary for ending the game. In addition to or instead of the above-mentioned notification being performed by the symbol display device 41, at least one of the display light emitting unit 53 and the speaker unit 54 may be configured.

When the confirmation return command is received from the main CPU 63 (step SH105: YES), the confirmation notification end processing is executed (step SH106). As described above, the return command for confirmation is transmitted to the sound-light side CPU 353 when the setting confirmation process (FIG. 258) is completed by the main side CPU 63. In the confirmation notification ending process, the notification corresponding to the setting confirmation process (FIG. 258) started in step SH102 is ended. After that, the post-confirmation notification table 521 is read from the sound-light side ROM 354 and written in the first execution area 531 of the sound-light side RAM 355 (step SH107). As a result, the post-confirmation notification is started by the display light emitting unit 53 and the speaker unit 54.

When the clear completion command is received from the main CPU 63 (step SH108: YES), the update notification end processing is executed (step SH109). As for the clear completion command, as described above, when the setting value update processing (FIG. 259) is ended in the main CPU 63, or the clear processing of the main RAM 65 is ended without executing the setting value update processing (FIG. 259). In this case, it is transmitted to the sound-light side CPU 353. In the update notification terminating process, in a situation after the update notification setting process is executed in step SH104, the set value update process (FIG. 259) started in the update notification setting process is performed. Terminate the corresponding notification. After that, the post-clearing notification table 522 is read from the sound-light side ROM 354 and written in the first execution area 531 of the sound-light side RAM 355 (step SH110). As a result, the post-clearing notification is started in the display light emitting unit 53 and the speaker unit 54.

When the main body opening command or the front door opening command is received from the main CPU 63 (step SH111: YES), the opening notification tables 523 and 525 corresponding to the opening command received this time are read from the sound-light side ROM 354 and the sound light is emitted. The data is written in the second execution area 532 of the side RAM 355 (step SH112). Specifically, when the main body opening command is received, the main body opening notification table 523 is read from the sound-light side ROM 354 and written in the second execution area 532 of the sound-light side RAM 355. When the front door opening command is received, the front door opening notification table 525 is read from the sound light side ROM 354 and written in the second execution area 532 of the sound light side RAM 355. As a result, the notification corresponding to the open notification tables 523 and 525 set in the second execution area 532 is displayed on the condition that the notification tables 521 and 522 are not set in the first execution area 531. And the speaker unit 54.

When the main body closing command or the front door closing command is received from the main CPU 63 (step SH113: YES), the closing notification tables 524 and 526 corresponding to the closing command received this time are read from the sound-light side ROM 354 and the sound light is emitted. The data is written in the third execution area 533 of the side RAM 355 (step SH114). Specifically, when the main body closing command is received, the main body closing notification table 524 is read from the sound-light side ROM 354 and written in the third execution area 533 of the sound-light side RAM 355. When the front door closing command is received, the front door closing notification table 526 is read from the sound-light side ROM 354 and written in the third execution area 533 of the sound-light side RAM 355. As a result, the third execution area 533 is set on condition that the notification tables 521 and 522 are not set in the first execution area 531 and the notification tables 523 and 525 are not set in the second execution area 532. The notification corresponding to the set closing notification tables 524 and 526 is started by the display light emitting unit 53 and the speaker unit 54.

In the production control process, in addition to the processes described above, other processes are executed in step SH115, and task processes are executed in step SH116. In other processing, when the command to start the game use effect is received from the main CPU 63, the symbol display device 41, the display light emitting unit 53, and the speaker unit 54 are used to start the game use effect. When the settings are made and the situation for the game use is to be advanced, the settings for advancing the game use effect are made by the symbol display device 41, the display light emitting section 53 and the speaker section 54, and the game time is set. When it is a situation in which the effect for use is to be ended, the pattern display device 41, the display light emitting unit 53, and the speaker unit 54 are set to end the effect for game play. Further, in other processing, when a command to start the effect for the opening/closing execution mode is received from the main CPU 63, the effect for the opening/closing execution mode is provided by the symbol display device 41, the display light emitting unit 53, and the speaker unit 54. In order to proceed with the opening/closing execution mode effect by the symbol display device 41, the display light emitting unit 53, and the speaker unit 54, when the setting for starting is performed and the effect for the opening/closing execution mode is to be advanced. When the setting is performed and the effect for the opening/closing execution mode is to be ended, the symbol display device 41, the display light emitting unit 53, and the speaker unit 54 are set for ending the effect for the opening/closing execution mode.

When executing the various effects, the effect execution table referred to for executing the effect is read into the effect execution area 534 provided in the sound-light side RAM 355 (see FIG. 262). The effect execution area 534 is set to an area having a lower execution priority than the first execution area 531, the second execution area 532, and the third execution area 533. Therefore, in the situation where the effect corresponding to the effect execution table set in the effect execution area 534 is being executed by the display light emitting unit 53 and the speaker unit 54, the first execution area 531, the second execution area 532, and the third execution area 532. When the notification tables 521 to 526 are set in any of the execution areas 533, the notification corresponding to the notification tables 521 to 526 is executed in the display light emitting unit 53 and the speaker unit 54 prior to the effect. To be done.

On the other hand, the effect corresponding to the effect execution table set in the effect execution area 534 is also performed in the symbol display device 41, and the display effect in the symbol display device 41 is the notification corresponding to the notification tables 521 to 526. Even if it is executed with priority, it will be executed continuously. As a result, it is possible to prevent an event in which the execution of all the productions is stopped in association with the execution of the notification corresponding to the notification tables 521 to 526.

Further, even when the notification corresponding to the notification tables 521 to 526 is executed with priority over the effect, the pointer information of the reference target in the effect effect table set in the effect execution area 534 is not updated. It is executed every time the update timing comes. Therefore, when the notification that is preferentially executed is finished and the execution of the effect in the display light emitting unit 53 and the speaker unit 54 is restarted, the effect corresponding to the display effect at that time in the symbol display device 41 is displayed and emitted. It can be restarted by the unit 53 and the speaker unit 54.

Next, the task processing executed in step SH116 will be described with reference to the flowchart in FIG. 267.

When the post-confirmation notification table 521 or the post-clearing notification table 522 is set in the first execution area 531 (step SH201: YES), the pointer update processing of the first execution area 531 is executed (step SH202). In the pointer update process, on condition that an update cycle of 40 milliseconds has elapsed since the pointer information of the reference target in the notification tables 521 and 522 set in the first execution area 531 was updated last time, The pointer information of the reference target in the notification tables 521 and 522 is updated to the pointer information in the next order. When the pointer information of the reference target exceeds the last pointer information in the notification tables 521 and 522 after updating the pointer information, the notification tables 521 and 522 are deleted from the first execution area 531.

When a negative determination is made in step SH201, or when the processing of step SH202 is executed, it is determined whether the main body opening notification table 523 or the front door opening notification table 525 is set in the second execution area 532. (Step SH203). When an affirmative determination is made in step SH203, pointer update processing for the second execution area 532 is executed (step SH204). In the pointer update processing, on the condition that an update cycle of 40 milliseconds has elapsed since the pointer information of the reference target in the notification tables 523 and 525 set in the second execution area 532 was updated last time, The pointer information of the reference target in the release notification tables 523 and 525 is updated to the pointer information in the next order. If the pointer information of the reference target exceeds the pointer information of the last order in the release notification tables 523 and 525 after updating the pointer information, the pointer information of the reference target is corrected to the pointer information of the first order. .. Further, if the main body opening notification table 523 is set in the second execution area 532, if the main body closing command is received from the main CPU 63, the main body opening notification table 523 is output from the second execution area 532. When the front door opening notification table 525 is set in the second execution area 532, when the front door closing command is received from the main CPU 63, the front door is deleted from the second execution area 532. The release notification table 525 is erased.

When a negative determination is made in step SH203 or when the processing of step SH204 is executed, it is determined whether or not the main body closing notification table 524 or the front door closing notification table 526 is set in the third execution area 533. (Step SH205). If an affirmative decision is made in step SH205, pointer update processing for the third execution area 533 is executed (step SH206). In the pointer update processing, on condition that an update cycle of 40 milliseconds has passed since the pointer information of the reference target in the closing notification tables 524 and 526 set in the third execution area 533 was updated last time. The pointer information of the reference target in the closing notification tables 524 and 526 is updated to the pointer information in the next order. If the pointer information of the reference target exceeds the last pointer information in the closing notification tables 524 and 526 after updating the pointer information, the notification tables 524 and 526 are deleted from the third execution area 533. ..

When a negative determination is made in step SH205, or when the processing of step SH206 is executed, it is determined whether or not the effect execution table is set in the effect execution area 534 (step SH207). When an affirmative determination is made in step SH207, pointer updating processing of the effect execution area 534 is executed (step SH208). In the pointer update process, the effect is provided on condition that an update cycle of 40 milliseconds has elapsed since the reference target pointer information in the effect execution table set in the effect execution area 534 was updated last time. The pointer information of the reference target in the execution table is updated to the pointer information in the next order. Further, after the pointer information is updated, if the pointer information of the reference target exceeds the last pointer information in the order in the effect execution table, the effect execution table is deleted from the effect execution area 534.

When a negative determination is made in step SH207 or when the processing of step SH208 is executed, it is determined whether or not the post-confirmation notification table 521 or the post-clearing notification table 522 is set in the first execution area 531 ( Step SH209). When an affirmative determination is made in step SH209, the display light emitting unit 53 is controlled using the light emission control data corresponding to the pointer information of the current reference target in the notification tables 521 and 522 set in the first execution area 531. The light emission control is performed and the sound output control data corresponding to the pointer information of the reference target is used to control the sound output of the speaker unit 54 (step SH210). After executing the processing of step SH210, this task processing ends.

When a negative determination is made in step SH209, it is determined whether or not the main body opening notification table 523 or the front door opening notification table 525 is set in the second execution area 532 (step SH211). When an affirmative determination is made in step SH211, the display light emitting unit 53 is controlled using the light emission control data corresponding to the pointer information of the current reference target in the notification tables 523 and 525 set in the second execution area 532. The light emission control is performed and the sound output control data corresponding to the pointer information of the reference target is used to control the sound output of the speaker unit 54 (step SH212). After executing the processing of step SH212, this task processing ends.

When a negative determination is made in step SH211, it is determined whether the main body closing notification table 524 or the front door closing notification table 526 is set in the third execution area 533 (step SH213). When an affirmative determination is made in step SH213, the display light emitting unit 53 is controlled using the light emission control data corresponding to the current pointer information of the reference target in the notification tables 524 and 526 set in the third execution area 533. The light emission control is performed and the sound output control data corresponding to the pointer information of the reference target is used to control the sound output of the speaker unit 54 (step SH214). After executing the processing of step SH214, this task processing is ended.

When a negative determination is made in step SH213, it is determined whether or not the effect execution area is set in the effect execution area 534 (step SH215). When an affirmative determination is made in step SH215, the light emission control of the display light emitting unit 53 is performed by using the light emission control data corresponding to the current pointer information of the reference target in the effect execution table set in the effect execution area 534. At the same time, the sound output control data corresponding to the pointer information of the reference target is used to control the sound output of the speaker unit 54 (step SH216). When a negative determination is made in step SH215 or after the processing of step SH216 is executed, this task processing is ended.

According to this embodiment described in detail above, the following excellent effects are exhibited.

When the setting value updating process (FIG. 259) is executed, the RAM clearing process (FIG. 260) is executed, so that the work area 221 for the specific control and the stack area 222 for the specific control are initialized. The area is initialized. As a result, when the set value update process (FIG. 259) is executed, it becomes possible to start the game in a situation where the area to be initialized has been initialized. Even when the area to be initialized is initialized in this way, the setting reference area 341 in which the information about the current setting value is stored is excluded from the initialization target. As a result, it is possible to start the game in a situation where the area to be initialized has been initialized when the setting value update process (FIG. 259) has been executed while not changing the setting value. ..

When the set value update process (FIG. 259) is executed and the RAM clear process (FIG. 260) is executed, the main CPU 63 sends a clear completion command to the sound/light side CPU 353 to execute post-clearing notification. It The manager of the gaming hall can confirm that the RAM clearing process (FIG. 260) has been executed by confirming that the notification has been executed after clearing, and the setting value updating process (FIG. 259). It is possible to understand that the process may have been executed.

Since the post-clearing notification is executed by the display light emitting unit 53 and the speaker unit 54, the manager of the game hall can confirm the post-clearing notification without requiring the opening operation of the gaming machine main body 12. Therefore, the manager of the gaming hall can easily understand that the RAM clearing process (FIG. 260) has been executed and also that the setting value updating process (FIG. 259) may have been executed.

Since the post-clearing notification is executed until 30 seconds elapse after the setting value updating process (FIG. 259) is executed, it becomes easier for the game hall manager to understand that the post-clearing notification is being executed.

Since the process for advancing the game is executed even in the situation where the post-clearing notification is being executed, it is possible to execute the post-clearing notification while not hindering the progress of the game.

Even if the setting key insertion unit 68a is not turned on, if the power is turned on while the reset button 68c is being pressed, the RAM is not set in the setting value updating process (FIG. 259). The clear processing (FIG. 260) is executed. In this case, the RAM clear process (FIG. 260) is executed when the RAM clear process (FIG. 260) is executed in the set value update process (FIG. 259) and when the set value update process (FIG. 259) is not executed. In either case, the same subroutine is called to initialize the initialization target areas of the specific control work area 221 and the specific control stack area 222, and execute the post-clearing notification. The processing for causing is performed. Thereby, while simplifying the processing configuration, it is possible to execute the processing for initializing the area to be initialized and the processing for executing the post-clearing notification in each of the above situations.

In the configuration in which the setting value update process (FIG. 259) is executed by turning on the setting key insertion portion 68a with the gaming machine main body 12 open and turning on the power while the reset button 68c is being pressed, Based on the fact that the gaming machine body 12 has changed from the open state to the closed state, the body closing notification is executed. As a result, after the game machine main body 12 is opened to illegally execute the set value update processing (FIG. 259), the game machine main body 12 is actually operated without illegally executing the set value update processing (FIG. 259). Even in the closed state, since the main body closing notification is executed after the closed state, the manager of the game hall can recognize the presence or absence of the fraudulent activity.

The post-clearing notification is set to have a higher execution priority than the main body closing notification. As a result, it is possible to directly notify that the set value update processing (FIG. 259) has been executed while enabling to notify whether the gaming machine main body 12 has been changed from the open state to the closed state. Become.

When the execution of the main body closing notification is not hindered due to the priority of the notification execution, in the configuration in which it is executed for 33 seconds after the gaming machine main body 12 is in the closed state, the post-clearing notification is issued more than the main body closing notification When the post-clearing notification is completed before 33 seconds elapse after the gaming machine main body 12 is closed, the post-clearing notification is executed for the remaining 33 seconds. To be done. Accordingly, in a configuration in which the post-clearing notification has a higher execution priority than the main body closing notification, the main body closing notification can be executed after the post-clearing notification ends. Further, even when the main body closing notification is executed after the post-clearing notification ends in this way, the execution period is required until the post-clearing notification ends after the gaming machine main body 12 is closed. The remaining period is obtained by subtracting the period from 33 seconds. This makes it possible to prevent the total execution period of these notifications from becoming excessively long when the main body closure notification is executed after the completion of the post-clearing notification.

The execution period of the main body closing notification is set to be longer than the execution period of the post-clearing notification. Accordingly, even when the post-clearing notification is prioritized over the main body closing notification, it is possible to ensure the execution period of the main body closing notification after the completion of the post-clearing notification.

When the setting confirmation process (FIG. 258) is executed, the main CPU 63 sends a return command for confirmation to the sound/light side CPU 353 to perform post-confirmation notification. The manager of the game hall can confirm that the setting confirmation process (FIG. 258) has been executed by confirming that the notification has been executed after the confirmation.

Since the post-confirmation notification is executed by the display light emitting unit 53 and the speaker unit 54, the manager of the game hall can confirm the post-confirmation notification without requiring the opening operation of the gaming machine main body 12. Therefore, the game hall manager can easily understand that the setting confirmation process (FIG. 258) has been executed.

Since the post-confirmation notification is executed until 30 seconds elapse after the setting confirmation process (FIG. 258) is executed, the game hall manager can easily understand that the post-confirmation notification is executed.

Since the process for advancing the game is executed even in the situation where the post-confirmation notification is executed, it is possible to execute the post-confirmation notification while not hindering the progress of the game.

In a configuration in which the setting confirmation process (FIG. 258) is executed by turning the power on while the gaming machine main body 12 is in the open state and the setting key insertion portion 68a is on, the gaming machine main body 12 is opened. The main body closing notification is executed based on the fact that the main body is closed. As a result, after the game machine main body 12 is opened to illegally execute the setting confirmation process (FIG. 258), the game machine main body 12 is actually operated without illegally executing the setting confirmation process (FIG. 258). Even in the case of the closed state, the main body closing notification is executed after the closed state, so that the manager of the gaming hall can grasp the presence or absence of the fraudulent activity.

The post-confirmation notification is set to have a higher execution priority than the main body closure notification. As a result, it becomes possible to directly notify that the setting confirmation processing (FIG. 258) has been executed while enabling to notify whether or not the gaming machine main body 12 has been changed from the open state to the closed state. ..

When the execution of the main body closing notification is not hindered due to the priority of the notification execution, in the configuration which is executed for 33 seconds after the gaming machine main body 12 is in the closed state, the notification after confirmation is issued rather than the main body closing notification. If the post-confirmation notification is completed before 33 seconds have elapsed after the gaming machine main body 12 is closed, the post-confirmation notification is executed for the remaining 33 seconds. To be done. Accordingly, in the configuration in which the post-confirmation notification has a higher execution priority than the main-body closure notification, it becomes possible to execute the main-body closure notification after the post-confirmation notification ends. Further, even when the main body closing notification is executed after the post-confirmation notification ends in this way, the execution period is required until the post-confirmation notification ends after the gaming machine main body 12 is in the closed state. The remaining period is obtained by subtracting the period from 33 seconds. This makes it possible to prevent the total execution period of the notifications from becoming excessively long when the main body closure notification is executed after the post-confirmation notification ends.

The execution period of the main body closing notification is set to be longer than the execution period of the post-confirmation notification. Accordingly, even when the post-confirmation notification is prioritized over the main body closing notification, it is possible to ensure the execution period of the main body closing notification after the post-confirmation notification ends.

The RAM clear process (FIG. 260) may be executed even when the setting confirmation process (FIG. 258) is executed. In this case, when the setting value is confirmed and the setting key insertion unit 68a is turned off, the RAM clearing process (FIG. 260) is executed, so that the setting control area other than the setting reference area 341 in the work area 221 for specific control is executed. Area is initialized, the stack area 222 for specific control is initialized, and a clear completion command is transmitted, so that the display light emitting unit 53 and the speaker unit 54 perform post-clearing notification. In this configuration, since the post-clearing notification is executed, the post-confirmation notification is not executed. That is, in the configuration, the common notification is executed regardless of which of the setting confirmation process (FIG. 258), the setting value update process (FIG. 259) and the RAM clear process (FIG. 260) is executed. Becomes

Further, the common post-clearing notification is executed regardless of whether the setting value updating process (FIG. 259) is executed or the RAM clearing process (FIG. 260) is executed independently. The present invention is not limited to this, and different notification may be performed depending on whether the set value updating process (FIG. 259) is executed or the RAM clearing process (FIG. 260) is executed.

Further, the notification period of the main body closing notification is not limited to 33 seconds, and may be a period longer than 33 seconds or a period shorter than 33 seconds. Further, the notification period of the body closing notification is not limited to the configuration in which the notification period of the body closing notification is longer than 30 seconds which is the notification period of the notification after confirmation and the notification after clearing, and the notification period of the body closing notification is after confirmation and clearing. The notification period of the post notification may be the same, or the notification period of the main body closure notification may be shorter than the notification period of the post-confirmation notification and the post-clear notification.

Further, the notification period of the main body opening notification is not limited to the configuration from when the gaming machine main body 12 is in the open state to when it is closed, and is set in advance after the gaming machine main body 12 is in the open state. Alternatively, the main body opening notification may be executed for a fixed period. In this case, the post-confirmation notification and the post-clearing notification are set to have a higher execution priority of the notification than the main body opening notification. If it remains, the main body release notification is executed for the remaining period.

In addition, instead of the configuration in which the main body opening notification is not performed when the power of the pachinko machine 10 is turned on while the main body 12 of the gaming machine is opened, the pachinko machine 10 is opened while the main body 12 of the game machine is opened. The main body opening notification may be performed even when the power is turned on. In this case, even if the setting confirmation process (FIG. 258) or the setting value update process (FIG. 259) is being executed, the display light emitting unit 53 and the speaker unit 54 continue to execute the main body opening notification. Becomes In the case where the post-confirmation notification or the post-clearance notification should be executed, the main body opening notification is ended due to the priority of the notification execution. When the gaming machine main body 12 is closed in the situation where the post-confirmation notification or the post-clearance notification is being executed, the main body opening notification is not executed as it is. In this case, after the post-confirmation notification or the post-clearance notification is completed, the main body closing notification is executed for the remaining period of the main body closing notification. On the other hand, if the gaming machine main body 12 is not closed in the situation where the post-confirmation notification or the post-clearing notification is being executed, the main body opening notification is restarted after the post-confirmation notification or the post-clearing notification is completed.

Further, in the setting value update process (FIG. 259), the RAM clear process (FIG. 260) is executed instead of the initial setting at the start (step SG703), so that the RAM clear process (FIG. 260) is not executed in step SG713. May be In this case, the clear completion command may be transmitted in the RAM clear process (FIG. 260), and the clear completion command is not transmitted in the RAM clear process (FIG. 260), but instead in step SG708. The clear completion command may be transmitted after making an affirmative determination.

Further, when the main CPU 63 transmits a return command for confirmation to the sound/light side CPU 353, an external output corresponding to the execution of the setting confirmation process (FIG. 258) is sent to the game hall management computer. It may be configured to be performed. Further, when a clear completion command is transmitted from the main CPU 63 to the sound-light CPU 353, an external output corresponding to the execution of the RAM clear processing (FIG. 260) is performed to the game hall management computer. May be

<75th Embodiment>
In the present embodiment, it is possible to allow the player to predict the set value set in the current pachinko machine 10 among the set values of “setting 1” to “setting 6” that determine the advantage of the pachinko machine 10. This is different from the 35th embodiment in that an effect is executed. The configuration different from that of the 35th embodiment will be described below. The description of the same configuration as the thirty-fifth embodiment is basically omitted.

FIG. 268 is a flowchart showing the first timer interrupt processing in this embodiment executed by the main CPU 63. The processing of steps SH301 to SH320 in the first timer interrupt processing is executed using the program for specific control and the data for specific control in the main CPU 63. In addition, the first timer interrupt process is periodically activated in the 4 msec cycle which is the first interrupt cycle as in the 35th embodiment.

In steps SH301 to SH305, steps S301 to S305 of the timer interrupt process (FIG. 11) in the first embodiment and steps S8901 to S8905 of the first timer interrupt process (FIG. 133) in the thirty-fifth embodiment. Perform the same processing. That is, power failure monitoring is executed by executing power failure information storage processing in step SH301. Specifically, similarly to the power failure information storage processing (FIG. 101) in the thirtieth embodiment, it is monitored whether or not a power failure signal corresponding to the occurrence of power shutdown is received from the power failure monitoring board 67, and the power failure is detected. When the occurrence of is specified, it becomes an infinite loop after executing the process at the time of power failure. In the power failure process, "1" is set to the power failure flag provided in the specific control work area 221, a checksum is calculated, and the calculated checksum is stored in the specific control work area 221. Further, by executing the random number updating process for lottery in step SH302, each numerical value information of the winning random number counter C1, the big hit type counter C2, the reach random number counter C3, and the general electric utility open counter C4 is updated, and in step SH303. The numerical information of the random number initial value counter CINI is updated by executing the random number initial value updating process, and the numerical information of the fluctuation type counter CS is updated by executing the fluctuation counter updating process in step SH304. Further, by executing the fraud detection process in step SH305, it is monitored whether or not an event set as a fraudulent monitoring target has occurred. In the fraud detection process, the occurrence of multiple types of events is monitored, and by confirming that any of these multiple types of events has occurred, the game stop provided in the work area 221 for specific control is stopped. Set "1" to the flag.

After executing the processing of steps SH301 to SH305, as in step S8906 of the first timer interrupt processing (FIG. 133) in the thirty-fifth embodiment, the game stop flag provided in the work area 221 for specific control Then, it is determined whether or not "1" is set in any of the start-up processing flags (step SH306). As in the thirty-fifth embodiment, the start-up processing in progress flag indicates that various types of processing set in the first timer interrupt processing (FIG. 268) are started even if the first timer interrupt processing (FIG. 268) is started. Among them, the process for performing power failure monitoring (step SH301), updating various counters (step SH302 to step SH304) and illegal monitoring (step SH305) is executed, while the process for advancing the game (step SH307 to step SH320). This is a flag for the main CPU 63 to specify that the first timer interrupt process (FIG. 268) should be terminated without executing the above. Note that the start-up processing flag is set when the main processing (FIG. 132) is started up and the processing at the start of supply of operating power (steps S8801 to S8819) is started, as in the 35th embodiment. "1" is set, and "0" is cleared when the process at the start of supplying the operating power (steps S8801 to S8819) is completed.

When "1" is set to at least one of the game stop flag and the startup flag (step SH306: YES), the first timer interrupt process (FIG. 268) without executing the processes of steps SH307 to SH320. ) Ends. That is, not only in the situation where the game stop flag is set to "1" but also when the startup processing flag is set to "1", the steps SH301 to SH301 in the first timer interrupt process (FIG. 268) While executing the processing of SH305, the processing of steps SH307 to SH320 is not executed.

When "1" is not set to both the game stop flag and the startup processing flag (step SH306: NO), the processing of steps SH307 to SH320 is executed. Specifically, in step SH307, port output processing is executed. In the port output process, when the output information is set in the previous first timer interrupt process, the process for outputting the various drive units 32b and 34b corresponding to the output information is executed.

After that, a reading process is executed (step SH308). In the reading process, signals other than the power failure signal and the winning signal are read, and the read information is stored for use in future processes.

After that, the ball detection processing is executed (step SH309). In the entrance detection process, the signals received from the entrance detection sensors 42a to 49a are read, and based on the read results, the outlet 24a, the general winning opening 31, the special prize winning device 32, and the first operating opening 33. The presence or absence of a ball entering the second operating port 34 and the through gate 35 is specified.

After that, a timer updating process for collectively updating the numerical value information of a plurality of types of timer counters provided in the main RAM 65 is executed (step SH310). In this case, the configuration is such that the timer counters that are updated by subtracting the stored numerical value information are aggregated and handled, but both the subtraction timer counter update and the addition timer counter update are aggregated and performed. It may be configured.

Then, the firing control process for controlling the firing of the game ball is executed (step SH311). In the situation where the firing operation to the firing operation device 28 is continued, one game ball is fired in a predetermined firing cycle of 0.6 seconds. In the following step SH312, as input state monitoring processing, based on the information read in the reading processing of step SH308, disconnection confirmation of each of the ball detection sensors 42a to 49a and open confirmation of the gaming machine main body 12 and the front door frame 14 are performed. I do.

After that, the special figure special electric power control processing for performing the execution control of the game times and the execution control of the opening/closing execution mode is executed (step SH313). The special figure special electric power control processing will be described later.

Then, the universal figure/universal control process is executed (step SH314). In the general/universal/universal control process, a process for acquiring the general/universal-university-side pending information is executed when a prize is paid to the through gate 35, and the general-universal/universal-side pending information is stored. Then, the release information is determined to be released, and the processing for performing the effect for the universal figure is executed when the release determination is triggered. In addition, based on the result of the open determination, a process of opening and closing the universal electric accessory 34a of the second operating port 34 is executed. In this case, if the support mode is the low frequency support mode, the corresponding process is executed, and if the support mode is the high frequency support mode, the corresponding process is executed. Further, in the case of the open/close execution mode, even if the support mode immediately before that is the high frequency support mode, it becomes the low frequency support mode.

In the following step SH315, based on the processing results of the immediately preceding steps SH313 and SH314, the output information for reflecting the increased/decreased number of the hold information related to the special figure display section 37a on the special figure hold display section 37b is set and The output information for reflecting the increased/decreased number of the hold information related to the universal figure display section 38a on the universal figure hold display section 38b is set. In step SH315, based on the processing results of the immediately preceding steps SH313 and SH314, output information for updating the display content of the special figure display portion 37a is set, and the display content of the general figure display portion 38a is changed. Set the output information for updating.

After that, the contents of the command and the signal received from the payout control device 77 are confirmed, and the payout state receiving process for performing the process corresponding to the confirmation result is executed (step SH316). Further, the payout output process for setting the prize ball command as the output target is executed (step SH317). In addition, the external information setting process for controlling the start and end of the output of the external signal according to the processing results of the various processes executed in the first timer interrupt process this time is executed (step SH318).

After that, the setting monitoring process is executed (step SH319), and further the management process is executed (step SH320). In the setting monitoring process, the same process as step S8220 of the first timer interrupt process (FIG. 117) in the thirty-third embodiment is executed. Specifically, it is determined whether or not the value of the set value counter in the work area 221 for specific control of the main RAM 65 corresponds to any of "setting 1" to "setting 6". When the value of the set value counter is "0" or "7" or more, it is determined that the set value is abnormal, and "1" is set to the game stop flag in the work area 221 for specific control.

When the game stop flag is set to "1", an affirmative determination is made in step SH306 of the first timer interrupt process (FIG. 268), whereby the process of steps SH307 to SH320 is not executed. As a result, when it is specified that the set value is abnormal, the progress of the game is stopped. On the other hand, even when the game stop flag is set to "1", the processing of steps SH301 to SH305 in the first timer interrupt processing (FIG. 268) is executed, so the progress of the game is stopped. Even in a situation where the power failure is monitored, the winning random number counter C1, the big hit type counter C2, the reach random number counter C3, and the random number initial value counter CINI are updated, and further fraud detection is executed.

After setting the game stop flag to "1", an abnormal command indicating that the set value is abnormal is transmitted to the sound emission control device 81. Upon receipt of the abnormal command, the voice emission control device 81 causes the display light emitting unit 53 to emit light in a manner corresponding to the abnormal set value, and causes the speaker unit 54 to output the voice "Please change the setting." .. Moreover, the character image "Please change the setting." is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are ended when the supply of operating power to the pachinko machine 10 is stopped. Even if the supply of the operating power to the pachinko machine 10 is temporarily stopped, the pachinko machine 10 is operated until the set value updating process (step S8819) of the main process (FIG. 132) in the 35th embodiment is executed. When the supply of the operating power is restarted, the above notification is continued and the state where the game stop flag is set to "1" is maintained. The manager of the game hall, who has confirmed the above notification in the situation where the progress of the game is stopped, temporarily stops the supply of operating power to the pachinko machine 10 and then resumes the supply of operating power to the pachinko machine 10. When the setting is performed, the operation for performing the set value updating process (step S8819) is performed. This makes it possible to set a new setting value in the setting value updating process (step S8819) when a setting value abnormality occurs.

The monitoring process for determining whether or not the set value is abnormal is executed by the first timer interrupt process (FIG. 268) that is regularly activated. Thereby, it becomes possible to monitor whether or not the set value is abnormal even in a situation where a game is being played. Therefore, it is possible to prevent the game from being continued even if the set value is abnormal. Further, the monitoring of whether or not the set value is abnormal is executed every time a monitoring trigger occurs. As a result, it is possible to increase the frequency of monitoring whether the set value is abnormal.

Next, the management process executed in step SH320 will be described. In the management process, the management execution process is executed similarly to the management process (FIG. 70) in the fifteenth embodiment, and the non-specific control program and the non-specific control data are used in the management execution process. Then, the check process is executed. FIG. 269 is a flowchart showing the check processing executed by the main CPU 63.

In the check process, when the front door frame 14 is in the open state (step SH401: YES), a normal ball entry management process (step SH404), a ball entry management process in the opening/closing execution mode (step SH405), and a high frequency. The result calculation process (step SH407) and the display process (step SH408) are executed without executing any of the entry management process (step SH406) in the support mode. Since the game area PA is formed by the space defined by the back surface of the window panel 52 provided on the front door frame 14 and the front surface of the game board 24, the front door frame 14 is opened. Even if the game area PA is opened toward the front and the game ball is shot toward the game area PA in that situation, the game ball cannot normally flow down the game area PA. Further, when the game balls enter the ball entrance portions 24a, 31 to 34 in a state where the front door frame 14 is in the open state, the game hall manager may perform maintenance or trouble elimination. This is a case where the front door frame 14 is opened and game balls enter due to care. Since the entry of such a game ball is not the entry of the game ball in the execution state of the regular game, it is not necessary to manage the entry of such a game ball. Therefore, in the check processing, if the front door frame 14 is in the open state as described above, none of the processing in steps SH404 to SH406 is executed.

When the front door frame 14 is in the closed state and is neither in the open/close execution mode nor the high frequency support mode (step SH401 to step SH403: NO), the normal entrance management process is executed (step SH404). When the front door frame 14 is in the closed state and is in the open/close execution mode (step SH401: NO, step SH402: YES), the ball entrance management process in the open/close execution mode is executed (step SH405). If the front door frame 14 is in the closed state and in the high frequency support mode (step SH401: NO, step SH403: YES), the ball entrance management process in the high frequency support mode is executed (step SH406). The processing content of the normal entrance management processing (step SH404) is the same as step S4004 of the check processing (FIG. 73) in the fifteenth embodiment, and the processing of the entrance management processing (step SH405) in the opening/closing execution mode. The contents are the same as step S4005 of the check process (FIG. 73) in the fifteenth embodiment, and the process contents of the entrance management process (step SH406) in the high frequency support mode are the check process in the fifteenth embodiment. This is similar to step S4006 of (FIG. 73).

That is, in the present embodiment, similar to the fifteenth embodiment, in the work area 223 for non-specific control, the normal counter area 231, the open/close execution mode counter area 232, and the high frequency support mode counter area 233 are provided. Are provided (see FIG. 72). In each of these areas 231-233, general prize winning counters 231a, 232a, 233a, special electric prize winning counters 231b, 232b, 233b, first operation counters 231c, 232c, 233c, second operation counters 231d, 232d, 233d, and Out counters 231e, 232e, 233e are provided. The general payout counters 231a, 232a, 233a are counters for measuring the number of game balls entered into the general payout opening 31 from a predetermined measurement start timing. The special electric prize winning counters 231b, 232b, 233b are counters for measuring the number of game balls entered into the special electric prize winning device 32 from a predetermined measurement start timing. The first operation counters 231c, 232c, 233c are counters for measuring the number of game balls entering the first operation port 33 from a predetermined measurement start trigger. The second operation counters 231d, 232d, 233d are counters for measuring the number of game balls entering the second operation port 34 from a predetermined measurement start trigger. The out counters 231e, 232e, 233e are counters for measuring the number of game balls entering the out port 24a from a predetermined measurement start trigger.

Each of the counters 231a to 231e in the normal counter area 231 is a target ball entry portion 24a in a situation where the front door frame 14 is in a closed state and is neither the open/close execution mode nor the high frequency support mode. It is used to count the number of game balls that enter 31 to 34. The measurement of the number of game balls is executed by a normal ball management process (step SH404). Each of the counters 232a to 232e in the opening/closing execution mode counter area 232 enters the target ball-in portion 24a, 31 to 34 in the situation where the front door frame 14 is in the closed state and the opening/closing execution mode is in effect. It is used to count the number of game balls played. The measurement of the number of game balls is executed in the ball entrance management process (step SH405) in the open/close execution mode. The counters 233a to 233e in the high-frequency support mode counter area 233 are the target ball-in portions 24a, 31 to 34 in the high-frequency support mode in which the front door frame 14 is closed. It is used to measure the number of game balls that enter the ball. The measurement of the number of game balls is executed in the ball entry management process (step SH406) during the high frequency support mode.

In addition, the situation where the front door frame 14 is in the open state is out of the measurement target because the game ball enters the ball entry portions 24a, 31 to 34 with the front door frame 14 open. This is because the number of entered balls in the case of being excluded is excluded from the measurement target. However, the present invention is not limited to this, and a configuration in which the front door frame 14 is in the open state may be a measurement target similarly to the situation in which the front door frame 14 is in the closed state.

The work area 223 for non-specific control is provided with a calculation result storage area 234 in addition to the normal counter area 231, the open/close execution mode counter area 232, and the high frequency support mode counter area 233. The calculation result storage area 234 is an area for storing information on the management result of the game history calculated by using the normal counter area 231, the opening/closing execution mode counter area 232, and the high frequency support mode counter area 233. .. The information on the management result of the game history stored in the calculation result storage area 234 is stored and held until the information on the management result of the game history is newly calculated to overwrite the newly calculated information.

Returning to the explanation of the check process (FIG. 269), if an affirmative judgment is made in step SH401, the process of step SH404 is executed, the process of step SH405 is executed, or the process of step SH406 is executed, The result calculation process is executed in SH407, and the display process is executed in step SH408.

In the display process of step SH408, the same process as the display process (FIG. 76) in the fifteenth embodiment is executed. However, in step S4306, display type data corresponding to the type of parameter corresponding to the value of the display target counter is set in the display target setting area 276. The display type data includes a display indicating which of the 61st to 68th parameters the notification target of the first to fourth notification display devices 201 to 204 is, the first notification display device 201 and the second notification display. This is display data to be executed by the device 202. Further, in step S4307, the parameter corresponding to the value of the display target counter is read from the calculation result storage area 234, and the calculation result data corresponding to the decimal point first digit and the decimal point second digit in the read parameter are obtained. It is set in the display target setting area 276.

The display type data and the calculation result data set as described above are set in the fifth display data buffer 275 in step S9007 of the second timer interrupt process (FIG. 134). Is displayed on the first to fourth notification display devices 201 to 204. In this case, on the first notification display device 201 and the second notification display device 202, a display indicating which of the 61st to 68th parameters is the notification target is performed. In addition, a display corresponding to the first decimal point number in the notification target parameter is performed on the third notification display device 203, and a display corresponding to the second decimal point number in the notification target parameter is the fourth notification. Display device 204. The display of one parameter on the first to fourth notification display devices 201 to 204 is continued for 10 seconds, and after being continued for 10 seconds, the display of the parameter to be notified in the next order is switched to.

FIG. 270 is a flowchart showing the result calculation process of step SH407.

First, it is determined whether or not "1" is set in the management start flag provided in the work area 223 for non-specific control (step SH501). The management start flag is a flag for the main CPU 63 to specify whether or not the game history collection for calculating the game history management result should be executed. In the present embodiment, when the supply of operating power to the pachinko machine 10 is started for the first time after the pachinko machine 10 is manufactured (that is, the supply of operating power to the MPU 62 is started), the game discharged from the game area PA. Until the total number of balls exceeds the number corresponding to the management start reference value, the total number of game balls discharged from the game area PA is not collected without collecting the game history for calculating the management result of the game history. When the number becomes greater than or equal to the management start reference value, the game history is collected to calculate the management result of the game history. When the pachinko machine 10 is shipped, for example, an operation check of the pachinko machine 10 may be performed before shipping, and in that case, a trial hit of a game ball may be performed. On the other hand, a game for calculating the management result of the game history until the total number of the game balls discharged from the game area PA after the start of the supply of the operating power to the pachinko machine 10 becomes the management start reference value or more. By not allowing the history to be collected, it is possible to prevent the result of entering the ball during the above operation check from being collected as the game history for calculating the management result of the game history. Become.

Here, when the supply of the operating power to the pachinko machine 10 is started for the first time after the pachinko machine 10 is manufactured (that is, the supply of the operating power to the MPU 62 is started), the value of the management start flag is “0”. Has become. In this case, the values of the counters 231a to 231e of the normal counter area 231, the values of the counters 232a to 232e of the open/close execution mode counter area 232, and the values of the counters 233a to 233e of the high-frequency support mode counter area 233. Is also "0". On the other hand, in a situation where the value of the management start flag is "1", the supply of operating power to the pachinko machine 10 is stopped, and then the operating power to the pachinko machine 10 is supplied in a situation where backup power is supplied to the main RAM 65. When the supply of No. is started, the value of the management start flag remains "1". In this case, the values of the counters 231a to 231e of the normal counter area 231, the values of the counters 232a to 232e of the open/close execution mode counter area 232, and the values of the counters 233a to 233e of the high frequency support mode counter area 233. Also, the state before the supply of the operating power to the pachinko machine 10 is stopped is maintained. With the above configuration, when the value of the management start flag is "0", the values of the counters 231a to 231e in the normal counter area 231 and the values of the counters 232a to 232e in the open/close execution mode counter area 232. The values of the counters 233a to 233e in the high-frequency support mode counter area 233 are also "0".

Incidentally, when the RAM clearing process is executed in step S8816 in the main process (FIG. 132), the target of the clearing process is the work area 221 for the specific control and the stack area 222 for the specific control. The work area 223 for specific control and the stack area 224 for non-specific control are excluded from the target of the clear processing. As a result, the game hall manager cannot intentionally clear the work area 223 for non-specific control and the stack area 224 for non-specific control to "0".

When a negative determination is made in step SH501, the values of the counters 231a to 231e in the normal counter area 231, the values of the counters 232a to 232e in the open/close execution mode counter area 232, and the high frequency support mode counter area 233 are determined. The total number is calculated by summing all the values of the counters 233a to 233e (step SH502). Then, it is determined whether or not the calculated total number is larger than the management start reference value “300” (step SH503).

When a positive determination is made in step SH503, "1" is set to the management start flag of the work area 223 for non-specific control (step SH504). Also, all the counters 231a to 231e in the normal counter area 231, the counters 232a to 232e in the open/close execution mode counter area 232, and the counters 233a to 233e in the high frequency support mode counter area 233 are all cleared to "0". (Step SH505). Thereby, the total number of game balls discharged from the game area PA after the supply of the operating power to the pachinko machine 10 is started (that is, after the supply of the operating power to the MPU 62 is started) is the management start reference value. All the game history information collected until the number of games corresponding to the above is exceeded will be erased. Therefore, after the start of the supply of the operating power to the pachinko machine 10, until the total number of game balls discharged from the game area PA becomes equal to or more than the management start reference value, the collection of the game history for calculating the management result of the game history. It becomes possible not to execute.

When an affirmative determination is made in step SH501, the calculation processing of the total number is executed similarly to step SH502 (step SH506). That is, the values of the counters 231a to 231e in the normal counter area 231, the values of the counters 232a to 232e in the open/close execution mode counter area 232, and the values of the counters 233a to 233e in the high-frequency support mode counter area 233 are set as follows. The total number is calculated by summing all. Then, it is determined whether or not the calculated total number is equal to or greater than the calculation reference number “60000” (step SH507). In the pachinko machine 10, a maximum of 100 game balls are fired per minute, so 60000 is the maximum number of shots in 10 hours. In this case, the general business hours in the game hall are about 13 hours, and the time during which the game is played is about 10 hours in the situation where neither the open/close execution mode nor the high-frequency support mode depending on the jackpot result. Therefore, the calculation reference number is set assuming the maximum number of game balls to be shot in one business day. The calculation reference number is not limited to 60,000, and may be a number smaller than 60,000, such as 6000, or a number larger than 60,000, such as 90,000.

When a positive determination is made in step SH507, arithmetic processing of various parameters is executed (step SH508). Specifically, the values of the various counters 231a to 231e in the normal counter area 231 are set to K61 to K65, the values of the various counters 232a to 232e in the open/close execution mode counter area 232 are set to K71 to K75, and the high frequency support mode is used. When the values of the various counters 233a to 233e in the counter area 233 are set to K81 to K85, the following 61st to 68th parameters are calculated.
61st parameter: total payout number of game balls (“K61+K71+K81”דnumber of prize balls for winning in the general winning opening 31”+“K62+K72+K82”דnumber of prize balls for winning in the special electric winning device 32”+“K63+K73+K83 "×"Number of prize balls for winning in the first operating port 33"+"K64+K74+K84" x "Number of prize balls for winning in the second operating port 34")/Total number of game balls discharged from the game area PA ( Ratio of K61+K62+K63+K64+K65+K71+K72+K73+K74+K75+K81+K82+K83+K84+K85) ・The 62nd parameter: the total payout amount of the game balls in the normal time (K61דthe number of prize balls for winning the prize at the general prize hole 31”+K62דthe special prize winning device 32”). X "Number of prize balls for winning in the first operating port 33" + K64 x "Number of prize balls for winning in the second operating port 34") / Total number of game balls discharged from the game area PA in the normal time (K61 + K62 + K63 + K64 + K65) ) 63rd parameter: total payout number of game balls in the open/close execution mode (K71 x "number of prize balls for winning in the general prize hole 31" + K72 x "number of prize balls for winning in the special prize winning device 32") +K73 x "number of prize balls for winning in the first operating port 33" +K74 x "number of prize balls for winning in the second operating port 34")/total of game balls discharged from the game area PA in the opening/closing execution mode Ratio of the number (K71+K72+K73+K74+K75) ・The 64th parameter: the total payout number of game balls in the high frequency support mode (K81 x "the number of prize balls for winning in the general winning hole 31" + K82 x "for winning the special electric prize device 32") "Number of prize balls" + K83 x "Number of prize balls for winning in the first operating port 33" + K84 x "Number of prize balls for winning in the second operating port 34")/is discharged from the game area PA in the high-frequency support mode percentage - 65 parameters of the total number of playing balls (K81 + K82 + K83 + K84 + K85): percentage of the total number of general total ball entrance number of game balls to winning hole 31 (K61 + K71 + K81) / game region game ball discharged from PA (K61 + K62 + K63 + K64 + K65 + K71 + K72 + K73 + K74 + K75 + K81 + K82 + K83 + K84 + K85) -66th parameter: the total number of entered game balls into the first operating port 33 (K63 + K7 3+K83)/total number of game balls discharged from the game area PA (K61+K62+K63+K64+K65+K71+K72+K73+K74+K75+K81+K82+K83+K84+K85) 67th parameter: The first operation port 33 and the second operation port 34 of the first operation port 33 + 64K number of the total number of the game ball 64 64K number of the game ball 63 + 64K number of game balls. )/(Total number of game balls discharged from the game area PA in normal time (K61+K62+K63+K64+K65)+Total payout number of game balls in normal time (K61דNumber of prize balls for winning in the general winning opening 31”+K62ד Ratio of the number of prize balls for winning in the special electric prize winning device 32+K63דthe number of prize balls for winning in the first working port 33”+K64דthe number of winning balls for winning in the second working port 34”) 68 parameters: (“K62+K72+K82”דthe number of prize balls for winning the special electric prize winning device 32”+“K64+K74+K84”דthe number of prize balls for winning the second working port 34”)/total payout number of game balls (“ “K61+K71+K81”דNumber of prize balls for winning in the general winning opening 31”+“K62+K72+K82”דNumber of prize balls for winning in the special electric prize winning device 32”+“K63+K73+K83”דPrize for winning in the first working opening 33” Ratio of “number of balls”+“K64+K74+K84”דnumber of prize balls for winning in second operation port 34”).

After that, the 61st to 68th parameters calculated in step SH508 are overwritten in the calculation result storage area 234 (step SH509). In this case, the 61st to 68th parameters of the calculation result in the previous processing times, which are already stored in the calculation result storage area 234, are erased. Even when the supply of the operating power to the pachinko machine 10 is stopped, the backup power is supplied to the main RAM 65. Therefore, if the backup power is supplied, the backup power is supplied to the pachinko machine 10. Even immediately after the start of the supply of the operating power, the calculation result storage area 234 stores the information of the 61st to 68th parameters calculated before the supply of the operating power to the pachinko machine 10 is stopped.

After that, all the counters 231a to 231e in the normal counter area 231, the counters 232a to 232e in the open/close execution mode counter area 232, and the counters 233a to 233e in the high frequency support mode counter area 233 are all cleared to "0". (Step SH510). As a result, when the 61st to 68th parameters are calculated, it becomes possible to temporarily erase the information of the game history at that time.

Immediately after the management start flag is set to "1", if the total number of game balls discharged from the game area PA is equal to or more than the value obtained by subtracting the management start reference value from the calculation reference number, step SH508- The processing of step SH510 may be executed, and thereafter, the processing of steps SH508 to SH510 may be executed when the total number of game balls discharged from the game area PA becomes equal to or larger than the calculation reference number.

Then, it is determined whether or not a predetermined parameter among the 61st to 68th parameters newly written in the calculation result storage area 234 this time is within the suggestion reference range (step SH511). Specifically, it is determined whether or not the content of the 67th parameter is included in the range of 1/20 to 1/10. The suggestion reference range is determined according to the specifications of the pachinko machine 10, and the specific numerical range is arbitrary.

When the content of the 67th parameter is included in the suggestion reference range (step SH511: YES), “1” is set to the suggestion reference flag provided in the work area 223 for non-specific control (step SH512), and the 67th parameter If the content of is not included in the suggestion reference range (step SH511: NO), the suggestion reference flag is cleared to “0” (step SH513). The suggestion reference flag is a flag for the main CPU 63 to specify whether or not the content of the 67th parameter calculated in the latest result calculation process is within the suggestion reference range. Since the suggestion reference flag is provided in the work area 223 for non-specific control, even if the supply of the operating power to the pachinko machine 10 is stopped, the backup reference power is supplied to the main RAM 65 so that the suggestion reference flag can be set. The stored state of information is maintained, and "0" is not cleared even if the RAM clear process is executed in step S8816 of the main process (FIG. 132).

Next, the special figure special power control processing executed in step SH313 of the first timer interrupt processing (FIG. 268) will be described with reference to the flowchart of FIG. The processes of steps SH601 to SH612 in the special drawing/special electric control process are executed by using the program for specific control and the data for specific control in the main CPU 63.

In steps SH601 to SH609, the same processing as steps S401 to S409 of the special drawing special power control processing (FIG. 12) in the first embodiment is executed, and in steps SH611 to SH612, the special processing in the first embodiment is executed. The same process as step S411 to step S412 of the figure special power control process (FIG. 12) is executed. In step SH610, the special electric power releasing processing is executed. FIG. 272 is a flowchart showing the special electric power releasing processing of step SH610. Note that the processing of steps SH701 to SH709 in the special electric power open processing is executed using the program for specific control and the data for specific control in the main CPU 63.

First, a round game progress process is executed (step SH701). In the process for the progress of the round game, the update process of the counter for measuring the number of winning game balls to the special electric prize winning device 32 provided in the main RAM 65 when the special electric prize winning device 32 has won. To execute. After that, it is determined whether or not the conditions for ending the round game are satisfied (step SH702). Specifically, when the winning number of game balls to the special electric winning device 32 generated in this round game is equal to or more than the upper limit number of the round game, it is determined that the round game ending condition is satisfied. .. Also, when the opening duration of the special electric winning device 32 in the round game this time has reached the upper limit duration, it is determined that the condition for ending the round game is satisfied.

When the ending condition of the round game is satisfied (step SH702: YES), the special power winning device 32 is closed by executing the closing setting process (step SH703). Further, the value of the round counter provided in the main RAM 65 is decremented by 1 (step SH704). The round counter is a counter for the main CPU 63 to specify the number of remaining round games to be generated in the open/close execution mode.

When the value of the round counter after subtracting 1 is not "0" (step SH705: NO), the interval period setting process is executed (step SH706). In the interval period setting process, the interval period for maintaining the closed state of the special electric prize winning device 32 is set until the timing to start the next round game. After that, by adding 1 to the value of the special figure special electric power counter, the numerical information of the counter is updated from the value corresponding to the special electric power open processing to the value corresponding to the special electric close processing (step SH707).

When the value of the round counter after subtracting 1 is "0" (step SH705: YES), the ending process is executed (step SH708). After that, by adding 2 to the value of the special figure special electric power counter, the numerical information of the counter is updated from the value corresponding to the special electric power open processing to the value corresponding to the special electric power termination processing (step SH709).

FIG. 273 is a flowchart showing the ending process of step SH708. The processes of steps SH801 to SH809 in the ending process are executed by using the specific control program and the specific control data in the main CPU 63.

First, the ending period setting process is executed (step SH801). In the ending period setting process, an ending period (for example, 10 seconds) in the current open/close execution mode is set. In the special electric power ending control processing (FIG. 271) special electric power ending processing (step SH612), if the ending period has elapsed, each of the winning/losing lottery mode and the support mode after the end of the opening/closing execution mode is opened/closed this time. The opening/closing execution mode of this time is ended by setting the mode corresponding to the jackpot result that triggered the start of the mode and then clearing the value of the special figure special electric power counter to “0”.

After executing the process of step SH801, in steps SH802 to SH809, a process for causing the display light emitting unit 53, the speaker unit 54, and the symbol display device 41 to execute the ending effect in the ending period of this time is executed. In the present embodiment, in the ending effect on the symbol display device 41, the suggestion effect of the set value that allows the player to predict the current set value set in the pachinko machine 10 can be executed.

274(a) and 274(b) are explanatory diagrams for explaining an example of the ending effect executed by the symbol display device 41. 274(a) and 274(b) are displayed on the symbol display device 41 as ending effects in opening/closing execution modes of different execution times. In both of FIGS. 274(a) and 274(b), the ending image CH1 (specifically, the character image of "END") is displayed on the symbol display device 41 as an image indicating the ending period. .. Also, in FIG. 274(a), the first suggestion character image CH2 is displayed in addition to the ending image CH1, and in FIG. 274(b), the second suggestion character image CH3 is displayed in addition to the ending image CH1. Has been done.

The first suggestion character image CH2 is an image displayed as the first suggestion effect in the ending effect. The first suggestive effect is an effect selected with the highest probability as the ending effect regardless of the setting of any of “setting 1” to “setting 6”. On the other hand, the second suggestion character image CH3 is an image displayed as the fifth suggestion effect in the ending effect. The fifth suggestive effect is an effect that is selected with the lowest probability as the ending effect regardless of which of "Setting 1" to "Setting 6" is set, and "Setting 1" to "Setting 6". Among these, a set value with a higher player's advantage is a production with a higher probability of being selected as an ending production. Therefore, even if the first suggestion character image CH2 is displayed on the symbol display device 41 during the ending period, which of the "setting 1" to "setting 6" is the current setting value of the pachinko machine 10 for the player? On the other hand, when the second suggestion character image CH3 is displayed on the symbol display device 41 during the ending period, the player sets the current setting value of the pachinko machine 10 to “setting 6”. It is possible to predict whether the set value has a high advantage.

In addition to the first suggestive effect and the fifth suggestive effect, the ending effect has a second suggestive effect, a third suggestive effect, and a fourth suggestive effect. In each of the first to fifth suggestive effects, the ending image CH1 is displayed and the suggesting character image (the first suggestive character image CH2 in the case of the first suggestive effect and the second suggestive effect in the case of the fifth suggestive effect). Although the for-use character image CH3) is displayed, the contents of the suggesting character image are different in each of the first to fifth suggestive effects. Therefore, the player can confirm which of the first to fifth suggestive effects is being performed as the ending effect by confirming the content of the suggesting character image.

For details of the processing after step SH802 in the ending processing (FIG. 273), it is first determined whether or not the current set value of the pachinko machine 10 is normal (step SH802). Specifically, it is determined whether or not the value of the set value counter in the work area 221 for specific control of the main RAM 65 corresponds to any of "setting 1" to "setting 6". When the value of the set value counter is “0” or “7” or more, it is determined that the set value is abnormal (step SH802: NO), and the first suggestion is made in the work area 221 for specific control in the main RAM 65. The effect information is stored (step SH803). Although the details of the first suggestion effect information will be described later, as the effect of the ending period of this time, the main CPU 63 is required to execute the first suggestion effect by the display light emitting unit 53, the speaker unit 54, and the symbol display device 41. Is information for specifying and identifying the sound emission control device 81.

When the value of the set value counter corresponds to any of "setting 1" to "setting 6", it is determined that the setting value is normal (step SH802: YES), and the non-specific control of the main RAM 65 is performed. It is determined whether or not "1" is set in the suggestion reference flag in the work area 223 (step SH804). As described above, the suggestion reference flag is a flag for the main CPU 63 to specify whether or not the content of the 67th parameter calculated in the latest result calculation processing (FIG. 270) is within the suggestion reference range. ..

If the suggestion criterion flag is set to "1" (step SH804: YES), that is, if the 67th parameter calculated in the most recent result calculation process (FIG. 270) is normal, the main side ROM 64 stores it. The lottery tables 541a to 541f (see FIG. 275) corresponding to the set values are read from the preset value suggestion lottery table group 541 stored in advance at the time of normal suggestion (step SH805). On the other hand, if the suggestion criterion flag is not set to "1" (step SH804: NO), that is, if the 67th parameter calculated in the latest result calculation process (FIG. 270) is not normal or is not yet the first parameter. When the 67 parameters are not calculated, the lottery tables 542a to 542f (see FIG. 275) corresponding to the set values are read from the suggestion limit set value suggestion lottery table group 542 stored in advance in the main ROM 64 (step 275). SH806). Although details will be described later, in the lottery table read in step SH805 or step SH806, the ending to be selected from the first suggestive effect, the second suggestive effect, the third suggestive effect, the fourth suggestive effect, and the fifth suggestive effect. Information on the type of effect is set, and the lottery value to be won is set corresponding to each ending effect to be selected so that the selection probability of the ending effect to be selected becomes a predetermined probability. ing.

After executing the processing of step SH805 or step SH806, the lottery processing of setting value suggestion is executed (step SH807). In the lottery process of setting value suggestion, the lottery value is acquired from the random number counter for ending effect that is regularly updated in the work area 221 for specific control of the main RAM 65, and the acquired lottery value is set in step SH805 and step. By collating with the lottery table read by any of SH806, suggestive effect information (first suggestive effect information, second suggestive effect information, second suggestive effect information, and second suggestive effect information corresponding to the suggestive effect to be executed in the ending effect this time is obtained. Any one of the 3 suggestion effect information, the 4th suggestion effect information and the 5th suggestion effect information) is read out.

Here, the set value suggestion lottery table group 541 for the normal suggestion and the set value suggestion lottery table group 542 for the suggestion limit will be described. FIG. 275 is an explanatory diagram for explaining the data configuration of the main ROM 64. In the main ROM 64, a set value suggestion lottery table group 541 for normal suggestion and a set value suggestion lottery table group 542 for suggestion limit are stored in advance. In the set value suggestion lottery table group 541 at the time of the normal suggestion, the table 1 for setting 1 at the time of the normal suggestion referred to when the set value of the pachinko machine 10 is “setting 1” and the set value of the pachinko machine 10 are provided. A table 2 for setting 2 at the time of normal suggestion referred to when it is “setting 2”, and a table 541c for setting 3 at the time of normal suggestion referred to when the set value of the pachinko machine 10 is “setting 3”. , The setting 4 table 541d for normal suggestion referred to when the set value of the pachinko machine 10 is "setting 4", and the normal suggestion referred to when the set value of the pachinko machine 10 is "set 5" There are an hour setting 5 table 541e and a normal suggestion time setting 6 table 541f that is referred to when the set value of the pachinko machine 10 is “setting 6”. In the suggestion limit setting value suggestion lottery table group 542, the suggestion limit setting 1 table 542a referred to when the set value of the pachinko machine 10 is “setting 1” and the set value of the pachinko machine 10 are provided. A suggestion limit setting 2 table 542b that is referred to when "setting 2" and a suggestion limit setting 3 table 542c that is referred to when the set value of the pachinko machine 10 is "setting 3". , The setting 4 table 542d at the time of suggestion limit referred to when the set value of the pachinko machine 10 is "setting 4", and the suggestion limit referred to when the set value of the pachinko machine 10 is "set 5" There are an hour setting 5 table 542e and a suggestion limit setting 6 table 542f that is referred to when the set value of the pachinko machine 10 is “setting 6”.

FIG. 276 is an explanatory diagram for explaining selection probabilities of the first to fifth suggestive effect information when each of the various tables 541a to 541f and 542a to 542f is selected.

When any of the settings 1 to 6 tables 541a to 541f for normal suggestion is referred to, any of the first to fifth suggestion effect information can be selected. However, the probability that the first suggestion effect information is selected is set to be highest in any of the settings 1 to 6 tables 541a to 541f at the time of normal suggestion. Specifically, in the tables 1 to 541a to 541c for the settings 1 to 3 at the time of normal suggestion, the probability that the first suggestion effect information is selected exceeds 50%, and the tables 541d to 541d to the settings 4 to 6 at the time of normal suggestion are set. Even with 541f, the first suggestion effect information is selected with a probability of about 50%. Therefore, even if the first suggestion effect is executed, it is difficult for the player to predict the current set value.

The second suggestion effect information is selected with a probability of 25% in the tables 541a, 541c, and 541e for the settings 1, 3, and 5 at the time of the normal suggestion, while the information for the settings 2, 4, and 6 at the time of the normal suggestion is selected. In the tables 541b, 541d, and 541f, selection is made with a probability of 10%. On the other hand, the third suggestion effect information is selected with a probability of 10% in the tables 541a, 541c, and 541e for the settings 1, 3, and 5 at the time of the normal suggestion, while the settings 2, 4, at the time of the normal suggestion are selected. In the 6 tables 541b, 541d, and 541f, selection is performed with a probability of 25%. That is, the second suggestive effect is likely to be executed when an odd set value is set, and the third suggestive effect is likely to be executed when an even set value is set. Therefore, when the second suggestive effect is executed, the player can predict that the odd set value is likely to be set, and when the third suggestive effect is executed, The player can predict that there is a high possibility that an even set value is set.

The fourth suggestion effect information is selected with a probability of 4% in the tables 1 to 541a to 541c for setting 1 to 3 at the time of normal suggestion, whereas in the tables 541d to 541f for setting 4 to 6 at the time of normal suggestion. It is selected with a probability of 10%. That is, the fourth suggestion effect is less likely to be executed when the setting value is "setting 1" to "setting 3" corresponding to the lower setting value, and "setting 4" to "setting corresponding to the higher setting value". In the case of "setting 6", the probability of execution is twice or more as compared with the case of "setting 1" to "setting 3". Therefore, when the fourth suggestion effect is executed, the player can predict that there is a high possibility that "setting 4" to "setting 6", which is the higher setting value, is set. ..

The fifth suggestion effect information is selected with a probability of 1% in the setting 1 and 2 tables 541a and 541b for the normal suggestion, and with a probability of 4% in the setting 3 table 541c for the normal suggestion. It is selected with a probability of 6% in the suggestion setting 4 table 541d, with 8% probability in the normal suggestion setting 5 table 541e, and 10% in the normal suggestion setting 6 table 541f. Is selected with the probability of. In other words, the fifth suggestive effect has a very low probability of being executed in “Setting 1” and “Setting 2”, and is more likely to be executed in “Setting 3” than in the cases of “Setting 1” and “Setting 2”. Although it is also high, it is still low, and the probability of execution in the order of “setting 4”→“setting 5”→“setting 6” is increasing. Therefore, when the fifth suggestion effect is executed, the player can predict that there is a high possibility that a setting value having a high degree of advantage is set.

When any of the settings 1 to 6 tables 542a to 542f for suggestion limitation is referred to, the first to third suggestive effect information can be selected, whereas the fourth and fifth suggestive effect information are not selected. Specifically, in the setting 1, 3, and 5 tables 542a, 542c, and 542e for suggestion restriction, the first suggestive effect information is selected with a probability of 65%, and the second suggestive effect information is selected with a probability of 25%. The third suggestion effect information is selected with a probability of 10%, whereas neither the fourth suggestion effect information nor the fifth suggestion effect information is selected. Further, in the settings 2, 4, and 6 tables 542b, 542d, and 542f for suggestion restriction, the first suggestive effect information is selected with a probability of 65%, and the second suggestive effect information is selected with a probability of 10%. While the 3 suggestive effect information is selected with a probability of 25%, neither the 4th suggestive effect information nor the 5th suggestive effect information is selected. That is, when any of the settings 1 to 6 tables 542a to 542f for suggestion restriction is referred to, one of the first to third suggestive effects is executed, and the fourth suggestive effect and the fifth suggestive effect are executed. Not done.

As described above, when the 67th parameter calculated in the latest result calculation process (FIG. 270) is normal, the setting 1 at the time of normal suggestion included in the set value suggestion lottery table group 541 at the time of normal suggestion 1 In contrast to the case where the lottery table corresponding to the set value is selected from the table for -6 to 541a to 541f, the content of the 67th parameter calculated in the latest result calculation process (FIG. 270) is abnormal. A suggestion-limited setting value suggestion lottery table group 542 includes a suggestion-limited setting 1-6 table 542a to 542f, and a lottery table corresponding to the set value is selected. In this case, when any of the tables 1 542a to 542f for setting 1 to 6 at the time of suggestion limitation is referred to as described above, one of the first to third suggestive effects is executed, and the fourth suggestive effect and the fifth suggestive effect are executed. Suggestive production is not executed. Thereby, when the content of the 67th parameter, that is, the winning probability to the first operation opening 33 or the second operation opening 34 in the normal time is not normal, an effect that suggests that the set value is on the high side is executed. It is possible to prevent it. Therefore, even if the winning probability to the first operating port 33 or the second operating port 34 is not normal, the player who confirms the effect suggesting that the set value is on the high side is stopped by the player. It is possible to prevent a situation in which the game is continued without being played.

On the other hand, not only the first suggestion effect but also the second suggestion effect and the third suggestion effect can be executed even when the settings 1 to 6 tables 542a to 542f at the time of suggestion limitation are referred to. Then, similarly to the case where the tables 1 541a to 541f for the settings 1 to 6 at the time of normal suggestion are referred to, the second suggestive effect is likely to be executed when an odd set value is set, and the third suggestive effect is even. It is easy to be executed when the set value of is set. Therefore, even in a situation where the winning probability to the first operation opening 33 or the second operation opening 34 is not normal, it is possible to suggest an odd set value and an even set value.

When it is determined in step SH802 in the ending process (FIG. 273) that the set value is abnormal, the set value suggestion lottery process (step SH807) is not executed, and the ending command is given the first suggestion effect information. Is set. This makes it possible to execute only the first suggestion effect as the ending effect when the set value is abnormal. However, the present invention is not limited to this, and when the set value is abnormal, a special effect indicating that the set value is abnormal may be executed as the ending effect.

In the result calculation processing (FIG. 270), if the calculated 67th parameter is normal, the suggestion reference flag in the work area 223 for non-specific control is set to "1". When the suggestion reference flag is set to "1", the suggestion reference flag is set to "1" by referring to the set value suggestion lottery table group 541 at the time of the normal suggestion in the set value suggestion lottery process. If there is no set value suggestion, the set value suggestion lottery table group 542 at the time of suggestion limitation is referred to in the lottery process for suggesting the set value. Therefore, in the situation where the 67th parameter has not been derived yet, the suggestion reference flag is not set to "1", and thus the set value suggestion lottery table group 542 at the time of suggestion limitation in the lottery process for suggesting the set value. Will be referred to. This makes it possible to prevent an effect that suggests that the set value is on the high side from being executed in a situation where it has not been specified whether the 67th parameter is normal.

Even in the situation where the 67th parameter has not been derived yet, the set value suggestion lottery table group 542 at the time of suggestion limitation is referred to as in the case where the content of the 67th parameter is abnormal. As a result, it is not necessary to prepare a dedicated table group in a situation where the 67th parameter has not been derived yet, and thus it is possible to suppress the required storage capacity.

Returning to the description of the ending process (FIG. 273), after executing the setting value suggestion lottery process in step SH807, the ending command is read from the main ROM 64, and the read ending command is returned to step SH803. Then, the first suggestion effect information stored in the specific control work area 221 or the suggestion effect information read in step SH807 is set (step SH808). Then, the ending command is transmitted to the sound emission control device 81 (step SH809).

FIG. 277 is a flowchart showing an ending effect control process executed by the CPU provided in the sound emission control device 81. The ending effect control process is started when an ending command is received from the main CPU 63.

When the first suggestion effect information is set in the ending command received this time (step SH901: YES), the setting process of the first suggestion effect is executed (step SH902). In the setting process of the first suggestive effect, an effect execution table for causing the display light emitting unit 53 and the speaker unit 54 to execute the first suggestive effect as the ending effect is output from the ROM provided in the sound emission control device 81. The data is read out to the RAM provided in the light emission control device 81. As a result, the ending effect corresponding to the first suggestion effect is executed as the light emission effect of the display light emitting unit 53 and the sound output effect in the speaker unit 54. In the setting process of the first suggestive effect, the ending command corresponding to the first suggestive effect is transmitted to the display control device 82. Upon receiving the ending command, the display control device 82 causes the symbol display device 41 to execute the ending effect corresponding to the first suggestion effect.

When the second suggestion effect information is set in the ending command received this time (step SH903: YES), the setting process of the second suggestion effect is executed (step SH904). In the setting process of the second suggestive effect, an effect execution table for causing the display light emitting unit 53 and the speaker unit 54 to execute the second suggestive effect as the ending effect is output from the ROM provided in the sound emission control device 81. The data is read out to the RAM provided in the light emission control device 81. Thereby, the ending effect corresponding to the second suggestion effect is executed as the light emission effect of the display light emitting unit 53 and the sound output effect in the speaker unit 54. In the second suggestion effect setting process, an ending command corresponding to the second suggestion effect is transmitted to the display control device 82. Upon receiving the ending command, the display control device 82 causes the symbol display device 41 to execute the ending effect corresponding to the second suggestion effect.

When the third suggestion effect information is set in the ending command received this time (step SH905: YES), the setting process of the third suggestion effect is executed (step SH906). In the setting process of the third suggestive effect, an effect execution table for causing the display light emitting unit 53 and the speaker unit 54 to execute the third suggestive effect as the ending effect is output from the ROM provided in the sound emission control device 81. The data is read out to the RAM provided in the light emission control device 81. Thereby, the ending effect corresponding to the third suggestion effect is executed as the light emitting effect of the display light emitting unit 53 and the sound output effect in the speaker unit 54. Further, in the setting process of the third suggestive effect, the ending command corresponding to the third suggestive effect is transmitted to the display control device 82. The display control device 82 causes the symbol display device 41 to execute the ending effect corresponding to the third suggestion effect by receiving the ending command.

When the fourth suggestion effect information is set in the ending command received this time (step SH907: YES), the setting process of the fourth suggestion effect is executed (step SH908). In the setting process of the fourth suggestion effect, an effect execution table for causing the display light emitting unit 53 and the speaker unit 54 to execute the fourth suggestion effect as the ending effect is output from the ROM provided in the sound emission control device 81. The data is read out to the RAM provided in the light emission control device 81. Thereby, the ending effect corresponding to the fourth suggestion effect is executed as the light emission effect of the display light emitting unit 53 and the sound output effect in the speaker unit 54. Further, in the setting process of the fourth suggestive effect, the ending command corresponding to the fourth suggestive effect is transmitted to the display control device 82. Upon receiving the ending command, the display control device 82 causes the symbol display device 41 to execute the ending effect corresponding to the fourth suggestion effect.

When the fifth suggestion effect information is set in the ending command received this time (step SH907: NO), the setting process of the fifth suggestion effect is executed (step SH909). In the setting process of the fifth suggestive effect, an effect execution table for causing the display light emitting unit 53 and the speaker unit 54 to execute the fifth suggestive effect as the ending effect is output from the ROM provided in the sound emission control device 81. The data is read out to the RAM provided in the light emission control device 81. Accordingly, the ending effect corresponding to the fifth suggestion effect is executed as the light emission effect of the display light emitting unit 53 and the sound output effect in the speaker unit 54. In the setting process of the fifth suggestive effect, the ending command corresponding to the fifth suggestive effect is transmitted to the display control device 82. Upon receiving the ending command, the display control device 82 causes the symbol display device 41 to execute the ending effect corresponding to the fifth suggestion effect.

According to this embodiment described in detail above, the following excellent effects are exhibited.

When the content of the 67th parameter calculated in the most recent result calculation process (FIG. 270) is normal, the tables for setting 1 to 6 at normal suggestion included in the set value suggestion lottery table group 541 at normal suggestion While the lottery table corresponding to the set value is selected from 541a to 541f, when the content of the 67th parameter calculated in the latest result calculation process (FIG. 270) is abnormal, the suggestion limit time is set. The lottery table corresponding to the set value is selected from the suggestion-limited setting 1 to 6 tables 542a to 542f included in the set value suggestion lottery table group 542. In this case, when any of the settings 1 to 6 tables 542a to 542f for suggestion limitation is referred to, one of the first to third suggestive effects is executed, and the fourth suggestive effect and the fifth suggestive effect. Is not executed. Accordingly, when the content of the 67th parameter is not normal, that is, when the winning probability to the first operating opening 33 or the second operating opening 34 in normal time is not normal, the setting value is higher. It is possible to prevent the suggested performance from being executed. Therefore, even if the winning probability to the first operating port 33 or the second operating port 34 is not normal, the player who confirms the effect suggesting that the set value is on the high side is stopped by the player. It is possible to prevent a situation in which the game is continued without being played.

On the other hand, not only the first suggestion effect but also the second suggestion effect and the third suggestion effect can be executed even when the settings 1 to 6 tables 542a to 542f at the time of suggestion limitation are referred to. Then, similarly to the case where the tables 1 541a to 541f for the settings 1 to 6 at the time of normal suggestion are referred to, the second suggestive effect is likely to be executed when an odd set value is set, and the third suggestive effect is even. It is easy to be executed when the set value of is set. Therefore, even in a situation where the winning probability to the first operation opening 33 or the second operation opening 34 is not normal, it is possible to suggest an odd set value and an even set value.

When the content of the 67th parameter is normal, the set value suggestion lottery table group 541 at the time of normal suggestion is referred to, and when the content of the 67th parameter is abnormal, the set value suggestion lottery table group 542 at the time of suggestion limitation is made. Is a configuration that refers to. As a result, it is possible to achieve the excellent effects as already described while reducing the processing load.

In the result calculation processing (FIG. 270), if the calculated 67th parameter is normal, the suggestion reference flag in the work area 223 for non-specific control is set to "1". When the suggestion reference flag is set to "1", the suggestion reference flag is set to "1" by referring to the set value suggestion lottery table group 541 at the time of the normal suggestion in the set value suggestion lottery process. If there is no set value suggestion, the set value suggestion lottery table group 542 at the time of suggestion limitation is referred to in the lottery process for suggesting the set value. Therefore, in the situation where the 67th parameter has not been derived yet, the suggestion reference flag is not set to "1", and thus the set value suggestion lottery table group 542 at the time of suggestion limitation in the lottery process for suggesting the set value. Will be referred to. This makes it possible to prevent an effect that suggests that the set value is on the high side from being executed in a situation where it has not been specified whether the 67th parameter is normal.

Even in the situation where the 67th parameter has not been derived yet, the set value suggestion lottery table group 542 at the time of suggestion limitation is referred to as in the case where the content of the 67th parameter is abnormal. As a result, it is not necessary to prepare a dedicated table group in a situation where the 67th parameter has not been derived yet, and thus it is possible to suppress the required storage capacity.

It should be noted that there may be a configuration in which there is a confirmed effect that is selected only when the setting effect is “setting 6”. In this case, the player who confirms the finalized effect will be convinced that the set value of the pachinko machine 10 is “setting 6”, and therefore the player will play the game while being immersed in the sense of superiority. In this configuration, if the set value of the pachinko machine 10 is “setting 6” when the content of the 67th parameter is normal, the finalized effect can be executed, whereas the content of the 67th parameter is abnormal. In some cases, even if the setting value of the pachinko machine 10 is “setting 6”, the final effect may not be executed. Further, such a configuration may be applied to a configuration in which only fixed effects are set as the suggested effects. In this case, an effect that does not contribute to the suggestion of the set value will be executed in the situation where the fixed effect is not executed. Further, in a situation in which the 67th parameter has not been derived yet, it may be configured such that the fixed effect is not executed even if the setting value of the pachinko machine 10 is “setting 6”.

Further, even when the content of the 67th parameter is abnormal, the second suggestive effect indicating that the set value of the pachinko machine 10 is an odd set value and the set value of the pachinko machine 10 is an even set value. However, the present invention is not limited to this, and when the content of the 67th parameter is abnormal, a suggestive effect that makes it possible to predict the set value is provided. The configuration may be such that it is not executed at all. In this case, when the content of the 67th parameter is abnormal, the first suggestion effect is executed regardless of the set value of the pachinko machine 10.

Further, when the content of the 67th parameter is abnormal, an effect that is not executed when the content of the 67th parameter is normal may be executed as the ending effect. In this case, when the type of ending effect executed when the content of the 67th parameter is abnormal is set to one type regardless of the set value of the pachinko machine 10 or the content of the 67th parameter is abnormal. The type of ending effect to be executed may be determined regardless of the set value of the pachinko machine 10. As a result, it is possible to prevent the effect suggesting the set value of the pachinko machine 10 from being executed even though the content of the 67th parameter is abnormal.

Further, when the 67th parameter has not been derived yet, an effect which is not executed when the content of the 67th parameter is normal may be executed as the ending effect. In this case, when the 67th parameter has not been derived yet, the type of ending effect executed is set to one type regardless of the set value of the pachinko machine 10, or when the 67th parameter has not yet been derived. The type of ending effect to be executed may be determined regardless of the set value of the pachinko machine 10. As a result, it is possible to prevent the effect suggesting the set value of the pachinko machine 10 from being executed even though the 67th parameter has not been derived yet.

Further, instead of the configuration in which the fourth suggestive effect and the fifth suggestive effect are not executed when the content of the 67th parameter is abnormal, the content of the 67th parameter is changed when the content of the 67th parameter is abnormal. The probability that the fourth suggestive effect and the fifth suggestive effect are executed may be lower than that in the normal case.

Further, the first reference value and the second reference value are set as the reference value of the 67th parameter, and when the 67th parameter is less than the first reference value, the type of suggestive effect is selected in the first mode. If the 67th parameter is greater than or equal to the first reference value and less than the second reference value, the type of suggestive effect is selected in the second mode, and if the 67th parameter is greater than or equal to the second reference value. May be configured such that the type of suggestive effect is selected in the third mode.

Further, the second suggestive effect can be executed regardless of whether the set value of the pachinko machine 10 is an odd number or an even number, but as a target of execution when the set value of the pachinko machine 10 is an odd number. The configuration in which the probability of selection is high has been described, but the configuration is not limited to this, and the second suggestion effect may be configured to be executed only when the set value of the pachinko machine 10 is an odd number.

Further, the third suggestion effect can be executed regardless of whether the set value of the pachinko machine 10 is an odd number or an even number, but as a target of execution when the set value of the pachinko machine 10 is an even number. Although the configuration in which the probability of selection is high has been described, the configuration is not limited to this, and the third suggestion effect may be configured to be executed only when the set value of the pachinko machine 10 is an even number.

Further, the set value is not limited to 6 steps, and may be 2 steps, 3 steps, 4 steps, 5 steps, 7 steps, 8 steps or 9 steps or more. Moreover, the configuration is not limited to the configuration in which the set values are serial numbers, and the configuration may be set as “setting a”, “setting b”, “setting c”, and “setting e”. In this case, the player's advantage increases in the order of “setting a”→“setting b”→“setting c”→“setting e”. In this configuration, when the setting value of the use target is either “setting a” or “setting c”, the second suggestive effect is executed or the probability that the second suggestive effect is executed is high, When the setting value of the use target is either “setting b” or “setting d”, the third suggestive effect may be executed or the probability that the third suggestive effect is executed may be increased.

Further, the content of the 67th parameter is not limited to that in the above-mentioned embodiment. For example, the 67th parameter is
As a ratio of the total number of game balls entering the first operation port 33 and the second operation port 34 in the normal time (K63+K64)/(the total number of game balls discharged from the game area PA in the normal time (K61+K62+K63+K64+K65)) The configuration may be derived.

Further, the effect suggesting the set value of the pachinko machine 10 is not limited to the configuration executed as the ending effect in the opening/closing execution mode, and in addition to or instead of this, the pachinko machine is an effect different from the ending effect. It may be configured such that an effect that suggests a set value of 10 is executed. For example, a configuration that suggests the set value of the pachinko machine 10 may be performed in the game-use production that is executed in the game play, and a production that suggests the set value of the pachinko machine 10 as the opening production of the opening/closing execution mode. May be configured to be executed, and as the effect in the round game in the opening/closing execution mode, an effect suggesting the set value of the pachinko machine 10 may be configured to be executed.

<76th Embodiment>
In this embodiment, the processing configuration of the ending process executed by the main CPU 63 is different from that in the 75th embodiment. The configuration different from that of the 75th embodiment will be described below. The description of the same configuration as the 75th embodiment is basically omitted.

FIG. 278 is a flowchart showing the ending process executed by the main CPU 63 in this embodiment. The processes of step SI101 to step SI109 in the ending process are executed by using the specific control program and the specific control data in the main CPU 63.

First, the ending period setting process is executed (step SI101). In the ending period setting process, an ending period (for example, 10 seconds) in the current open/close execution mode is set. In the special electric power ending control processing (FIG. 271) special electric power ending processing (step SH612), if the ending period has elapsed, each of the winning/losing lottery mode and the support mode after the end of the opening/closing execution mode is opened/closed this time. The opening/closing execution mode of this time is ended by setting the mode corresponding to the jackpot result that triggered the start of the mode and then clearing the value of the special figure special electric power counter to “0”.

Then, it is determined whether or not the current set value of the pachinko machine 10 is normal (step SI102). Specifically, it is determined whether or not the value of the set value counter in the work area 221 for specific control of the main RAM 65 corresponds to any of "setting 1" to "setting 6". When the value of the set value counter is “0” or “7” or more, it is determined that the set value is abnormal (step SI102: NO), and the first suggestion is made in the work area 221 for specific control in the main RAM 65. The effect information is stored (step SI107). In this case, the first suggestion effect information is set to the ending command (step SI108), and the ending command is transmitted to the sound emission control device 81 (step SI109). As a result, the first suggestive effect is executed as the ending effect as in the 75th embodiment. Therefore, in a situation where there is an abnormality in the set value, it is possible to prevent the ending effect from performing the effect that enables prediction of the set value.

When the value of the set value counter corresponds to any of "setting 1" to "setting 6", it is determined that the setting value is normal (step SI102: YES), and the current setting value is read from the main ROM 64. The lottery table corresponding to is read (step SI103). In the present embodiment, the set value suggestion lottery table group 542 at the time of suggestion limitation is not prepared as the table group referred to in the set value suggestion lottery process, but the set value suggestion lottery table group 541 at the time of normal suggestion is prepared. ing. The setting suggestion lottery table group 541 at the time of the normal suggestion has the tables 1 541a to 541f for the settings 1 to 6 at the time of the normal suggestion as in the above-mentioned 75th embodiment. The contents of the usage tables 541a to 541f are the same as in the 75th embodiment. In step SI103, the table corresponding to the set value of the pachinko machine 10 out of the tables 1 541a to 541f for setting 1 to 6 at the time of normal suggestion is read from the main ROM 64.

Then, a lottery process for setting value suggestion is executed (step SI104). In the lottery process of setting value suggestion, the lottery value is acquired from the random number counter for ending effect which is regularly updated in the work area 221 for specific control of the main RAM 65, and the acquired lottery value is obtained in step SI103. By collating with the read lottery table, suggestive effect information (first suggestive effect information, second suggestive effect information, third suggestive effect information, third suggestive effect information, and Either one of the 4 suggestive effect information and the 5th suggestive effect information) is read out.

Then, it is determined whether or not "1" is set in the suggestion reference flag in the work area 223 for non-specific control of the main RAM 65 (step SI105). Similar to the 75th embodiment, the suggestion reference flag specifies in the main CPU 63 whether or not the content of the 67th parameter calculated in the latest result calculation process (FIG. 270) is the suggestion reference range. It is a flag for.

If the suggestion reference flag is set to "1" (step SI105: YES), that is, if the 67th parameter calculated in the most recent result calculation process (FIG. 270) is normal, the set value suggestion The suggestion effect information selected in the lottery process (step SI104) is set as the ending command (step SI108), and the ending command is transmitted to the sound emission control device 81 (step SI109). As a result, the suggestion effect corresponding to the suggestion effect information selected in the setting value suggestion lottery process (step SI104) is executed as the ending effect. Therefore, the player can predict the set value of the pachinko machine 10 from the content of the ending effect.

On the other hand, if the suggestion criterion flag is not set to "1" (step SI105: NO), that is, if the 67th parameter content calculated in the latest result calculation process (FIG. 270) is not normal, the set value is set. It is determined whether or not the suggestion effect information selected in the suggestion lottery process (step SI104) is the fourth suggestion effect information or the fifth suggestion effect information (step SI106). When the suggestion effect information selected in the setting value suggestion lottery process (step SI104) is the first suggestion effect information, the second suggestion effect information, or the third suggestion effect information (step SI106: NO), the set value suggestion lottery The suggestion effect information selected in the process (step SI104) is set to the ending command (step SI108), and the ending command is transmitted to the sound emission control device 81 (step SI109). This makes it possible to predict whether the current set value is an odd number or an even number even if the 67th parameter calculated in the latest result calculation process (FIG. 270) is not normal. It becomes possible to execute the possible second suggestion effect or the third suggestion effect.

When the suggestion effect information selected in the setting value suggestion lottery process (step SI104) is the fourth suggestion effect information or the fifth suggestion effect information (step SI106: YES), the selected suggestion effect information is invalidated. The first suggestion effect information is stored (step SI107). In this case, the first suggestion effect information is set to the ending command (step SI108), and the ending command is transmitted to the sound emission control device 81 (step SI109). As a result, the first suggestive effect is executed as the ending effect as in the 75th embodiment. Therefore, in the situation where the content of the 67th parameter calculated in the latest result calculation process (FIG. 270) is not normal, the fourth suggestion effect and the fourth suggestive effect that suggest that the current set value is the higher set value. It is possible to prevent 5 suggestive effects from being executed.

According to the above configuration, the latest result calculation process (FIG. 270) is possible without preparing the set value suggestion lottery table group 542 at the time of suggestion limitation as a table group to be referred to in the set value suggestion lottery process (step SI104). In a situation where the content of the 67th parameter calculated in step 6 is not normal, it is possible not to execute the fourth suggestion effect and the fifth suggestion effect that suggest that the current setting value is the higher setting value. It will be possible. Therefore, it is possible to preferably perform the suggestion effect of the set value while suppressing an increase in the storage capacity.

<77th Embodiment>
This embodiment is different from the forty-ninth embodiment in that the display segments of the first to fourth notification display devices 201 to 204 are turned off based on the fact that the progress of the game has been stopped. ing. Further, it differs from the forty-ninth embodiment in that a start waiting effect is performed. Hereinafter, a configuration different from that of the 49th embodiment will be described. Note that the description of the same configuration as the 49th embodiment is basically omitted.

First, a configuration for turning off the display segments of the first to fourth notification display devices 201 to 204 when the progress of the game is stopped will be described. In the first to fourth notification display devices 201 to 204, similar to the forty-ninth embodiment, the display corresponding to the management result of the game history is performed, and the setting confirmation process (FIG. 166) or the set value update is performed. When the process (FIG. 167) is executed, the display corresponding to the current set value is displayed.

As described above with reference to FIG. 119 in the thirty-third embodiment, the main control board 61 is provided with data corresponding to the supplied display data for each of the plurality of display segments of the special figure display portion 37a. Corresponding to the supplied display data, and a second display circuit 262 for providing data corresponding to the supplied display data to each of the plurality of display segments of the special figure reservation display unit 37b. A third display circuit 263 that provides data to each of the plurality of display segments of the public figure display section 38a, and data corresponding to the supplied display data to each of the plurality of display segments of the general figure hold display section 38b. A fifth display that provides a fourth display circuit 264 to be provided and data corresponding to the supplied display data to each of the plurality of display segments provided in each of the first to fourth notification display devices 201 to 204. And a circuit 265.

Similarly to the 33rd embodiment, the first to fifth display circuits 261 to 265 can store and hold the provided display data for a predetermined period (for example, 16 milliseconds), but After a lapse of time, the display data gradually approaches the state of all "0". Therefore, the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, the general figure reservation display unit 38b, and the display segments of the first to fourth notification display devices 201 to 204 are newly added. The display data is not provided to the corresponding display circuits 261 to 265, and the light is gradually turned off after a predetermined period has elapsed. In the present embodiment, when the progress of the game is stopped, the special figure display unit 37a is set by the state where new display data is not provided to the first to fifth display circuits 261 to 265. , The special figure reservation display unit 37b, the general figure display unit 38a, the general figure reservation display unit 38b, and the display segments of the first to fourth notification display devices 201 to 204 are set in the non-display state, that is, in the off state.

As described above with reference to FIG. 119 in the thirty-third embodiment, one display IC 266 is provided so as to be common to all the first to fifth display circuits 261 to 265. The main CPU 63 and the display IC 266 are electrically connected using the type data signal line LN1, the type clock signal line LN2, the display data signal line LN3, and the display clock signal line LN4. The CPU 63 supplies the display IC 266 with display data and type data indicating which of the first to fifth display circuits 261 to 265 the display data corresponds to.

As described above with reference to FIG. 121 in the thirty-third embodiment, the display IC 266 includes the type data buffer 281 in which the type data received from the main CPU 63 is stored, and the first to fifth display circuits 261 to 265. Of the display signals 261 to 265 corresponding to the type data stored in the type data buffer 281 as a receiving destination of the display data, and a selection signal output unit 282 that outputs from the main CPU 63. A display data buffer 283 that stores display data and a display data output unit 284 that transmits the display data stored in the display data buffer 283 to the first to fifth display circuits 261 to 265 are provided. When the type data stored in the type data buffer 281 is all “0” type data, the display data output unit 284 does not transmit the display data to any of the first to fifth display circuits 261 to 265. It becomes a state. In the present embodiment, when the progress of the game is stopped, the type data of all “0” is transmitted from the main CPU 63 to the display IC 266, and the type data of all “0” is sent to the type data buffer 281. Is stored. As a result, the display data is not transmitted to any of the first to fifth display circuits 261 to 265.

As described above with reference to FIG. 120(a) in the thirty-third embodiment, the work area 221 for specific control stores display data for causing the special figure display unit 37a to perform a predetermined display. A first display data buffer 271, a second display data buffer 272 in which display data for causing the special figure reservation display section 37b to perform a predetermined display is stored, and a general figure display section 38a performing a predetermined display. Third display data buffer 273 for storing display data for storing the display data, fourth display data buffer 274 for storing display data for causing the universal figure reservation display unit 38b to perform a predetermined display, and first to fourth A fifth display data buffer 275 storing display data for causing the notification display devices 201 to 204 to perform a predetermined display is provided.

In the present embodiment, when the progress of the game is not stopped, the main CPU 63 uses the display data buffers 271-275 corresponding to the processing times at each processing time of the second timer interrupt processing (FIG. 281) described later. The display data is read, the read display data is transmitted to the display IC 266, and the type data indicating which of the first to fifth display circuits 261 to 265 the display data corresponds to is transmitted to the display IC 266. .. The transmitted type data is stored in the type data buffer 281 of the display IC 266, and the transmitted display data is stored in the display data buffer 283. Then, the type data stored in the type data buffer 281 is transmitted from the selection signal output unit 282, and the display data stored in the display data buffer 283 is transmitted from the display data output unit 284. As a result, the display data is provided to the display circuits 261 to 265 specified by the type data, and the special figure display section 37a, the special figure hold display section 37b, the general figure display section 38a, the general figure display section 37a, the general figure display section 38a, The figure hold display unit 38b or each display segment of the first to fourth notification display devices 201 to 204 emits light.

On the other hand, when the progress of the game is stopped, in the present embodiment, the type data and the display data are not transmitted to the display IC 226 in the second timer interrupt process (FIG. 281) described later. .. By setting the display IC 266 in a state in which new type data and display data are not provided, the state in which the type data buffer 281 stores all type “0” type data is continued, and the first to fifth display circuits 261 are provided. It is possible to continue the state in which the display data is not transmitted to any of ~265. As a result, when the progress of the game is stopped, the special figure display section 37a, the special figure hold display section 37b, the general figure display section 38a, and the general figure hold display section 38b are released until the state is released. , And the off state of each display segment of the first to fourth notification display devices 201 to 204 can be continued.

Next, the first timer interrupt processing in this embodiment executed by the main CPU 63 will be described with reference to the flowchart in FIG. 279. As with the forty-ninth embodiment, when the setting confirmation process (FIG. 166) is executed in step SB112 of the main process (FIG. 165), the interrupt of the first timer interrupt process is performed in step SB115. It is permitted when the update process (FIG. 167) is executed and when the interrupt permission is set in step SB128. The processes of steps SI201 to SI220 in the first timer interrupt process are executed by using the specific control program and the specific control data in the main CPU 63. In addition, the first timer interrupt process is periodically activated in the 4 msec cycle which is the first interrupt cycle as in the 35th embodiment.

In steps SI201 to SI204, the same processing as steps S8901 to S8904 of the first timer interrupt processing (FIG. 133) in the thirty-fifth embodiment is executed. Specifically, the power failure information storage process is executed in step SI201. In the power outage information storage process, similarly to the power outage information storage process (FIG. 101) in the thirtieth embodiment, it is monitored whether or not a power outage signal corresponding to the occurrence of power shutdown is received from the power outage monitoring board 67, When the occurrence of a power failure is specified, an infinite loop is executed after executing the power failure process. In the power failure process, "1" is set to the power failure flag provided in the specific control work area 221, a checksum is calculated, and the calculated checksum is stored in the specific control work area 221.

After performing the power failure information storage process in step SI201, by performing the random number updating process for lottery in step SI202, the winning random number counter C1, the jackpot type counter C2, the reach random number counter C3, and the general electric utility open counter C4 are executed. The numerical information of the random number initial value counter CINI is updated by updating each numerical value information, and the random number initial value updating process is executed in step SI203, and the fluctuation type counter is executed by executing the fluctuation counter updating process in step SI204. The numerical information of CS is updated.

Then, fraud detection processing is executed (step SI205). In the present embodiment, detection of an illegal electric wave, detection of an illegal magnetism, and detection of an abnormal vibration are set as an illegality to be monitored in the illegality detection processing. Before describing the fraud detection process, a sensor for monitoring fraud will be described. FIG. 280(a) is an explanatory diagram for explaining a sensor for monitoring fraud.

As shown in FIG. 280(a), on the input side of the MPU 62, a radio wave detection sensor 551 for detecting an illegal radio wave, a magnetic detection sensor 552 for detecting an illegal magnetism, and an abnormal vibration are detected. The vibration detection sensor 553 is connected. When the radio wave detection sensor 551 detects an illegal radio wave, a radio wave abnormality signal is transmitted to the main CPU 63, and when the magnetic detection sensor 552 detects an illegal magnetism, a magnetic abnormality signal is transmitted to the main CPU 63, When the vibration detection sensor 553 detects abnormal vibration, a vibration abnormality signal is transmitted to the main CPU 63. When the main CPU 63 receives these abnormal signals, the main CPU 63 identifies that the illegality of the monitoring target has occurred.

Next, the fraud detection process executed by the main CPU 63 will be described with reference to the flowchart of FIG. 280(b). Note that the processes of step SI301 to step SI311 in the fraud detection process are executed using the program for specific control and the data for specific control in the main CPU 63. The fraud detection process is executed in step SI205 of the first timer interrupt process (FIG. 279).

In the fraud detection process, first, it is determined whether or not the game stop flag in the specific control work area 221 of the main RAM 65 is set to "1" (step SI301). As for the game stop flag, in the first timer interrupt process (FIG. 279), a positive determination is made in step SI206, which will be described later, and the process of steps SI207 to SI219 is not executed, that is, the execution of the process for advancing the game is stopped. This is a flag for the main CPU 63 to specify whether or not the situation should be met. When the game stop flag is set to "1", an affirmative determination is made in step SI206 of the first timer interrupt processing (FIG. 279), and the processing in steps SI207 to SI219 is not executed.

When it is determined in step SI301 that "1" is not set in the game stop flag, it is determined whether or not an illegality to be monitored has occurred (step SI302). Specifically, when the radio wave abnormality signal is received from the radio wave detection sensor 551, the magnetic abnormality signal is received from the magnetic detection sensor 552, or the vibration abnormality signal is received from the vibration detection sensor 553, the illegality of the monitoring target is detected. Determined to have occurred.

When it is determined that the monitored injustice has occurred (step SI302: YES), the game stop flag is set to "1" (step SI303). As described above, by setting the game stop flag to "1", an affirmative determination is made in step SI206, which will be described later, of the first timer interrupt processing (FIG. 279), and the processing in steps SI207 to SI219 is not executed. The situation, that is, the execution of the process for advancing the game is stopped. In this way, the progress of the game is stopped when the illegality of the monitored object occurs. On the other hand, even if the game stop flag is set to "1", the processes of steps SI201 to SI205 in the first timer interrupt process (FIG. 279) are executed. Therefore, even if the progress of the game is stopped, power failure monitoring is executed, and the winning random number counter C1, the big hit type counter C2, the reach random number counter C3, and the random number initial value counter CINI are updated, and Fraud detection is performed.

On the other hand, when it is determined in step SI301 that the game stop flag is set to "1", it is determined whether the game stop corresponding flag provided in the work area 221 for specific control is set to "1". The determination is made (step SI304). For the game stop corresponding flag, the type data buffer 281 and the display data buffer 283 (FIG. 121) of the display IC 266 (FIG. 121) are set after the game stop flag is set to “1” and the progress of the game is stopped. This is a flag that enables the main CPU 63 to know that the processing for clearing (the processing of step SI306 to step SI310) has been executed. The game stop corresponding flag is set to "1" in step SI311 described later. The game stop corresponding flag is cleared to "0" when the second RAM clearing process (step SB313) is executed in the set value updating process (FIG. 167) of the forty-ninth embodiment. If an affirmative determination is made in step SI302 due to the occurrence of fraud of the monitoring target, since the game stop corresponding flag is set to "1" in step SI311 described later, fraud detection processing (see FIG. In the subsequent processing times of b)), an affirmative judgment is made in step SI304.

As already described in the forty-ninth embodiment, when it is determined in step SB104 of the main process (FIG. 165) that the power failure flag is not set to "1", it is determined in step SB105 that the checksum is not normal. Also, or when it is determined in step SB106 that the setting reference area 341 is not within the normal range, "1" is set in the game stop flag (step SB119). After the game stop flag is set to "1" in step SB119, if the reset button 68c is not pressed (step SB120: NO), or the reset button 68c is pressed, the setting key is inserted. When the ON operation of the portion 68a is not performed (step SB120: YES, step SB114: NO), the first timer interrupt process (FIG. 279) is executed in step SB128 with the game stop flag set to "1". ), the fraud detection process (FIG. 280(b)) is executed in step SI205 of the first timer interrupt process. In the fraud detection process in this case, after the affirmative judgment is made in step SI301 based on the fact that the game stop flag is set to "1", the game stop corresponding flag is not set to "1". Based on the above, a negative determination is made in step SI304.

The game stop corresponding flag is a flag that is set to "1" on the condition that "1" is set to the game stop flag. In the state where "1" is set in the game stop flag and the game stop corresponding flag, after the supply of the operating power to the pachinko machine 10 is stopped, the reset button 68c is pressed and the setting key insertion portion 68a is turned on. The operation power supply to the pachinko machine 10 is started in the state where the operation is being performed, and the setting value update processing (FIG. 167) is canceled on the condition that it is executed. As already described in the forty-ninth embodiment, after the game stop flag is set to "1" in step SB119 of the main process (FIG. 165), the reset button 68c is pressed and the setting key insertion portion 68a is turned on. If it is performed (step SB120: YES, step SB114: YES), the set value update process is executed (step SB115). The game stop flag is cleared to "0" by the initial setting at the start in step SB303 of the set value update processing (FIG. 167), and the game stop corresponding flag is set in the set value update processing (FIG. 167). By executing the second RAM clear processing (step SB313), "0" is cleared.

Returning to the description of the fraud detection process (FIG. 280(b)), if the game stop flag is set to "1" in step SI303, or the game stop corresponding flag is not set to "1" in step SI304. If determined, the display data buffer clearing process is executed (step SI305). In the display data buffer clearing process, the first to fifth display data buffers 271 to 275 (FIG. 120(a)) provided in the specific control work area 221 are cleared to "0". As a result, after the supply of operating power to the pachinko machine 10 is stopped with the game stop flag set to "1", the ON operation of the setting key insertion portion 68a and the pressing operation of the reset button 68c are performed. When the supply of the operating power to the pachinko machine 10 is restarted in the state (that is, when the “setting change operation” is performed), the supply of the operating power to the first to fifth display data buffers 271 to 275 before the supply of the operating power is stopped. It is possible to prevent the setting value update processing (FIG. 167) from being started in the state where the display data remains.

After that, in steps SI306 to SI310, processing for clearing the type data buffer 281 and the display data buffer 283 of the display IC 266 is executed. Specifically, the transmission state of the signal through the type data signal line LN1 and the type clock signal line LN2 (FIG. 119) is set to the OFF state so that the type data is not transmitted (step SI306). Further, the transmission state of the signal through the display data signal line LN3 and the display clock signal line LN4 (FIG. 119) is set to the OFF state so that the display data is not transmitted (step SI307).

Then, the type data of all "0" is set as the type data of the transmission target to the display IC 266 (step SI308). The type data of all “0” is data for clearing the type data buffer 281 of the display IC 266 to “0”. As described above, the type data buffer 281 is a buffer that the display IC 266 refers to in order to know the destination of the display data stored in the display data buffer 283. When the type data buffer 281 is cleared to “0”, the display IC 266 does not transmit the display data. After the type data of all "0" is set in step SI308, the display data of all "0" is set as the display data to be transmitted to the display IC 266 (step SI309). The display data of all “0” is data for clearing the display data buffer 283 of the display IC 266 to “0”. By clearing the display data buffer 283 to “0”, the state where display data that does not correspond to the type data stored in the type data buffer 281 remains in the display data buffer 283 is eliminated.

After that, the transmission processing of various signals is executed (step SI310). In the various signal transmission processing, signals are output to the type data signal line LN1 and the type clock signal line LN2 so that the type data of all “0” set in step SI308 is transmitted to the display IC 266. As a result, the type data buffer 281 of the display IC 266 is cleared to “0”, and the display data is not provided to any of the first to fifth display circuits 261 to 265. Further, in the transmission processing of various signals in step SI310, signal output to the display data signal line LN3 and the display clock signal line LN4 is performed so that the display data of all “0” set in step SI309 is transmitted to the display IC 266. To do. As a result, the display data buffer 283 of the display IC 266 is cleared to “0”, and the state where the display data that does not correspond to the type data stored in the type data buffer 281 remains in the display data buffer 283 is eliminated.

After executing the transmission processing of various signals in step SI310, "1" is set to the game stop corresponding flag in the work area 221 for specific control (step SI311), and this fraud detection processing is ended. By setting the game stop support flag to "1", an affirmative determination is made in step SI304 in the next processing cycle of the fraud detection processing (FIG. 280(b)), and the processing in steps SI305 to SI311 is executed. It will not be executed.

As described above, when the game stop flag is set to "1" and the progress of the game is stopped, the type data buffer 281 of the display IC 266 is cleared to "0", whereby the first to fifth The display data is not provided to any of the display circuits 261 to 265.

Returning to the explanation of the first timer interrupt processing (FIG. 279), when the fraud detection processing is executed in step SI205, either the game stop flag or the startup processing flag in the specific control work area 221 is set to " It is determined whether "1" is set (step SI206). As in the forty-ninth embodiment, the start-up processing flag is among the various processes set in the first timer interrupt processing (FIG. 279) even if the first timer interrupt processing (FIG. 279) is activated. While the power outage monitoring, the processing for updating various counters, and the illegality monitoring are executed, the first timer interrupt processing (FIG. 279) should be terminated without executing the processing for advancing the game. This is a flag for specifying by the main CPU 63. When "1" is not set to both the game stop flag and the startup processing flag (step SI206: NO), the processing of steps SI207 to SI220 is executed. In Step SI207 to Step SI219, the same processing as Step S8907 to Step S8919 of the first timer interrupt processing (FIG. 133) in the 35th embodiment is executed.

On the other hand, if it is determined in step SI206 that "1" is set in at least one of the game stop flag and the in-progress processing flag, the process proceeds to step SI220 without executing the processes of step SI207 to step SI219. .. In this way, when at least one of the game stop flag and the startup processing flag is set to "1", the process for advancing the game is not executed.

If an affirmative decision is made in step SI206, or if the processing of step SI219 has been carried out, then management processing is executed (step SI220), and this first timer interrupt processing is terminated. In the management process in step SI220, the program of the management execution process (FIG. 71) corresponding to the non-specific control is read in step S3803 as in the management process (FIG. 70) in the fifteenth embodiment. Then, in this management execution processing, the check processing (FIG. 73) is executed in step S3908 as in the case of the fifteenth embodiment. In the check process (FIG. 73), in the situation where neither the open/close execution mode due to the jackpot result nor the high frequency support mode is specified, when a single game ball is identified to enter the general winning opening 31, a normal ordinary game When the value of the prize counter 231a is incremented by 1 and the entry of one game ball into the special prize winning device 32 is specified, the value of the normal special prize prize counter 231b is incremented by 1, and the first working port 33 is added. When the entry of one game ball is specified, the value of the normal first operation counter 231c is incremented by 1, and when the entry of one game ball into the second operation port 34 is specified Adds 1 to the value of the normal second operation counter 231d, and adds 1 to the value of the normal out counter 231e when the entry of one game ball into the out port 24a is specified. Further, in the checking process, a normal entrance management process (FIG. 74), a result calculation process (FIG. 130), and a display process (FIG. 131) are executed.

As already described in the thirty-fifth embodiment, the base value is the total number of game balls discharged from the game area PA in the situation where neither the open/close execution mode by the big hit result nor the high frequency support mode (that is, the game area PA). It is the ratio of the total payout number of game balls to the total number of game balls supplied to. When "1" is set to the game stop flag, the firing control process (step SI211) is not executed in the first timer interrupt process (FIG. 279), and thus the launch of a new game ball is prohibited. However, if a game ball exists in the game area PA at the timing when the game stop flag is set to "1", the game ball existing in the game area PA is set to "1" in the game stop flag. After being played, it will be discharged from the game area PA.

For example, the fraud detection process (FIG. 280(b)) is executed in a situation where a game ball exists in the game area PA, and the fraud of the monitoring target is detected in the fraud detection process (FIG. 280(b)). In this case, it is possible that the game stop flag is set to "1" before the game balls existing in the game area PA are discharged.

Assuming that the normal entry management process (FIG. 74) is not executed when the game stop flag is set to "1", the game area PA is discharged after the game stop flag is set to "1". The number of game balls will not be added to the normal out counter 231e. On the other hand, in the present embodiment, the normal ball-entry management process (FIG. 74) is executed even after the game stop flag is set to "1" and the game progress is stopped. Is. As a result, the number of game balls discharged from the game area PA after the game stop flag is set to "1" can be counted by the normal out counter 231e, and the game stop flag is set to "1". It is possible to calculate a base value that reflects the number of game balls discharged from the game area PA after being set.

In the present embodiment, the result calculation process (FIG. 130) is executed even when the game stop flag is set to "1". As already described in the thirty-fifth embodiment, in the result calculation process (FIG. 130), the base value calculation process is executed (step S8601). In the arithmetic processing, various counters 231a to 231e in the normal counter area 231 (the above-mentioned normal general prize winning counter 231a, normal special electric prize winning counter 231b, normal first operation counter 231c, normal second operation) The base value is calculated using the values of the counter 231d and the normal out counter 231e), and the calculated base value is used as the current area 311 (FIG. 126) in the calculation result storage area 234 of the non-specific control work area 223. ) Is overwritten (step S8602). As described above with reference to FIG. 126 in the thirty-fifth embodiment, the work area 223 for non-specific control is provided with the calculation result storage area 234, and the calculation result storage area 234 has the latest base. The current area 311 in which the value is stored, the first history area 312 in which the final base value in the previous calculation period is stored, and the first base area 312 in which the final base value in the previous calculation period is stored. A second history area 313 and a third history area 314 in which the final base value in the calculation period three times before is stored are provided.

After that, it is determined whether the management start flag provided in the work area 223 for non-specific control is set to "1" (step S8603). Similar to the 35th embodiment, the management start flag has a value of “0” when the supply of operating power to the pachinko machine 10 is started for the first time after the pachinko machine 10 is manufactured. Further, when the work area 223 for non-specific control is also initialized by clearing "0" including the management start flag, the value of the management start flag becomes "0". As already described in the thirty-fifth embodiment, since the management start flag is provided, the effect of the operation check at the shipping stage of the pachinko machine 10 is that a normal game is performed after the pachinko machine 10 is shipped. It is possible to make it harder for the base value in a certain situation.

If it is determined in step S8603 that the management start flag is not set to "1", the total number is calculated by summing all the values of the various counters 231a to 231e in the normal counter area 231 (step S8604). If the calculated total number is greater than the management start reference number of 300 (step S8605: YES), the management start flag is set to "1" (step S8606). Thereafter, a data shift process described later is executed (step S8607), and all the counters 231a to 231e in the normal counter area 231 are cleared to "0" (step S8608).

On the other hand, when it is determined in step S8603 that the management start flag is set to "1", the total number is calculated by summing all the values of the various counters 231a to 231e in the normal counter area 231 (step S8609). If the calculated total number is less than or equal to the initial reference number (specifically, 6000) (step S8610: NO), the operation initial flag provided in the work area 223 for non-specific control is set to "1". Is set (step S8611), and if the calculated total number is greater than the initial reference number (specifically, 6000) (step S8610: YES), the computation initial flag is cleared to “0”. (Step S8612). Similar to the 35th embodiment, the calculation initial flag is discharged from the game area PA in a situation where the base value calculation period is newly started and the open/close execution mode or the high frequency support mode depending on the jackpot result is neither. This is a flag for the main CPU 63 to specify whether or not the total number of game balls (that is, the total number of game balls supplied to the game area PA) has reached the initial reference number.

When the process of step S8611 or step S8612 is executed and the total number calculated in step S8609 is equal to or larger than the shift reference number (specifically, 60000) (step S8613: YES), the data shift process is executed. (Step S8614). In the data shift processing in steps S8607 and S8614, the information stored in the current state area 311, the first history area 312, the second history area 313, and the third history area 314 in the calculation result storage area 234 is converted into the second history area 313. →The third history area 314, the first history area 312, the second history area 313, the current area 311 and the first history area 312 are shifted in this order. As a result, the final base value in the calculation period two times before is stored in the third history area 314 as the final base value in the calculation period three times before, and the final base value in the calculation period one time before. Is stored in the second history area 313 as the final base value in the calculation period two times before, and the last calculated base value in the current calculation period is calculated as the final base value in the calculation period one time before. One history area 312 is stored. When the data shift process is performed, the current area 311 is cleared to “0”. The present value area 311 is overwritten with the base value calculated in step S8601 described above in the subsequent processing times of this result calculation processing (FIG. 130) (step S8602).

In the present embodiment, the result calculation process (FIG. 130) is executed even after the game stop flag is set to "1", so that the base value is maintained even after the progress of the game is stopped. And the data management for calculating the base value are continued. This makes it possible to calculate a base value that reflects up to the number of game balls discharged from the game area PA after the game stop flag is set to "1". In addition, based on the base value reflected up to the number of game balls discharged from the game area PA after the game stop flag is set to "1" and the progress of the game is stopped, the above-described management start It becomes possible to perform flag state setting, operation initial flag state setting, and data shift processing (step 8607 and step S8614).

Next, the second timer interrupt process executed by the main CPU 63 will be described with reference to the flowchart of FIG. As with the forty-ninth embodiment, when the setting confirmation process (FIG. 166) is executed in step SB112 of the main process (FIG. 165), the second timer interrupt process sets the set value in step SB115. It is permitted when the update process (FIG. 167) is executed and when the interrupt permission is set in step SB128. The processing of steps SI401 to SI415 in the second timer interrupt processing is executed in the main CPU 63 using the specific control program and the specific control data.

In the second timer interrupt process, it is first determined whether or not "1" is set in the game stop flag in the work area 221 for specific control (step SI401). As described above, the game stop flag is set to “1” in step SI303 of the fraud detection process (FIG. 280(b)) when the fraud of the monitoring target occurs. Further, in the game stop flag, as already described in the forty-ninth embodiment, when it is determined that the power failure flag is not set to "1" in the main process (FIG. 165) (step SB104: NO), If it is determined that the checksum is not normal (step SB105: NO), or if the setting reference area 341 is not within the normal range (step SB106: NO), "1" is set in step SB119. It

After it is determined in step SI401 that "1" is not set in the game stop flag, in steps SI402 to SI415, steps S9001 to S9014 of the second timer interrupt process (FIG. 134) in the 35th embodiment described above are performed. Perform the same processing. Specifically, in step SI402, by setting the interrupt prohibition, the generation of the first timer interrupt process (FIG. 279) and the second timer interrupt process (FIG. 281) is prohibited.

After that, the updating process of the checking counter is executed (step SI403). In the updating process of the checking counter, when the value of the checking counter provided in the work area 221 for specific control is 1 or more, the value of the checking counter is decremented by 1. As a result, when the initial check period is being measured using the checking counter, the value of the checking counter is periodically subtracted every time the second timer interrupt process (FIG. 281) is started. The Rukoto.

After that, when the setting update display flag in the specific control work area 221 is set to "1" (step SI404: YES), the setting process for the fifth display data buffer 275 during the setting update is executed. , A display indicating that the setting values of the pachinko machine 10 are being updated on the first to fourth notification display devices 201 to 204 (FIG. 53) and a display indicating the current setting values of the pachinko machine 10. The display data to be executed is stored in the fifth display data buffer 275 (step SI405). As a result, similar to the 33rd embodiment, on the first to fourth notification display devices 201 to 204, a display indicating that the setting value is being updated and a display indicating the current setting value. Is done.

On the other hand, when the setting update display flag in the specific control work area 221 is not set to "1" (step SI404: NO), the setting confirmation display flag in the specific control work area 221 is set to "1". It is determined whether or not (step SI406). Then, when the setting confirmation display flag is set to "1" (step SI406: YES), the setting process for the fifth display data buffer 275 during the setting confirmation is executed, and the first to fourth notifications are performed. The fifth display data buffer stores display data for displaying that the display devices 201 to 204 are confirming the setting values of the pachinko machine 10 and displaying the current setting values of the pachinko machine 10. 275. As a result, similar to the 33rd embodiment described above, a display indicating that the setting value is being confirmed and a display indicating the current setting value on the first to fourth notification display devices 201 to 204. Is done.

On the other hand, if "1" is not set in the setting confirmation display flag (step SI406: NO), the normal setting process is executed (step SI408). Similar to the 35th embodiment, in the normal setting process, when the value of the checking counter provided in the specific control work area 221 is 1 or more, the first to fourth notification displays are displayed. A check display is displayed on the devices 201 to 204. When the value of the checking counter is “0” and the management start flag provided in the work area 223 for non-specific control is not set to “1”, the management start flag is set to “1”. The base value is displayed in the situation where it is not set. In addition, when the management start flag is set to “1”, the display of the base value in the current area 311, the first history area 312, the second history area 313, and the third history area 314 (FIG. 126) is performed first. It is sequentially executed by the first to fourth notification display devices 201 to 204. In this case, the base value to be notified on the first to fourth notification display devices 201 to 204 is the current area 311 → the first history area every time the display continuation period (specifically, 5 seconds) elapses. It is switched in a predetermined order of 312→second history area 313→third history area 314. In this case, when the initial display flag provided in the work area 223 for non-specific control is set to "1", the calculation initial display is displayed on the first and second notification display devices 201 and 202. Done. In the calculation initial display, when the display corresponding to the display data currently set in the fifth display data buffer 275 is displayed on the first and second notification display devices 201 and 202, the display blinks. ..

When the process of step SI405 is executed, the process of step SI407 is executed, or the process of step SI408 is executed, the signal transmission state through the type data signal line LN1 and the type clock signal line LN2 is in the OFF state. At the same time (step SI409), the signal transmission state through the display data signal line LN3 and the display clock signal line LN4 is turned off (step SI410).

After that, the update processing of the type counter provided in the work area 221 for specific control is executed (step SI411). The type counter is a main CPU 63 that transmits the display data among the first to fifth display data buffers 271 to 275 in the processing time of the second timer interrupt processing in the state where "1" is not set in the game stop flag. It is a counter for specifying in. When the value of the type counter is "1", the display data of the first display data buffer 271 is the transmission target, and when the value of the type counter is "2", the display data of the second display data buffer 272 is the transmission target. When the value of the type counter is “3”, the display data of the third display data buffer 273 is the transmission target, and when the value of the type counter is “4”, the display data of the fourth display data buffer 274 is When it becomes a transmission target and the value of the type counter is “5”, the display data of the fifth display data buffer 275 becomes a transmission target. In the process of updating the type counter in step SI411, the value of the type counter is incremented by 1, and if the value of the type counter after adding 1 exceeds the upper limit value of "5", the value of the type counter is increased by "1". Set to. As a result, the transmission target of display data is sequentially changed in the first to fifth display data buffers 271 to 275 for each processing time of the second timer interrupt processing.

After that, the type data corresponding to the value of the type counter is read from the main ROM 64 (step SI412), and the display data is read from the display data buffers 271-275 corresponding to the value of the type counter (step SI413). Then, the transmission processing of various signals is executed (step SI414). In the transmission processing of various signals, signals are output to the type data signal line LN1 and the type clock signal line LN2 so that the type data read in step SI412 is transmitted to the display IC 266. In the transmission processing of various signals, signals are output to the display data signal line LN3 and the display clock signal line LN4 so that the display data read in step SI413 is transmitted to the display IC 266. After that, the interrupt permission is set (step SI415), and the second timer interrupt process is ended. In step SI415, the generation of the first timer interrupt process (FIG. 279) and the second timer interrupt process (FIG. 281) is permitted.

On the other hand, when it is determined in step SI401 that the game stop flag is set to "1", the second timer interrupt process is ended without executing the various processes of step SI402 to step SI415. As a result, when the game stop flag is set to "1" and the progress of the game is stopped, new type data and display data can not be transmitted to the display IC 266.

As described above, when "1" is set in the game stop flag, the type data buffer of the display IC 266 is executed by executing the processing of step SI306 to step SI311 of the fraud detection processing (FIG. 280(b)). 281 and the display data buffer 283 are cleared to "0", and the display data is not provided to the first to fifth display circuits 261 to 265. Further, as described above, when the game stop flag is set to "1", the various processes of step SI402 to step SI415 in the second timer interrupt process (FIG. 281) are not executed, so that the display IC 266 is As a result, new type data and display data will not be transmitted. As a result, the state in which new display data is not provided to the first to fifth display circuits 261 to 265 is continued until the state in which the game stop flag is set to "1" is released. You can

As described above, the first to fifth display circuits 261 to 265 can store and hold the provided display data for a predetermined period (for example, 16 milliseconds), but when the predetermined period elapses, the display data is not stored. It gradually approaches the state of all "0". Therefore, when new display data is not provided to the first to fifth display circuits 261 to 265, the special figure display section 37a, the special figure hold display section 37b, the general figure display section 38a, and the general figure are displayed. The hold display unit 38b and the display segments of the first to fourth notification display devices 201 to 204 are in a non-display state, that is, in a light-off state.

As described above, the base values are displayed on the first to fourth notification display devices 201 to 204. If the display of the base value is continued on the first to fourth notification display devices 201 to 204 even when the progress of the game is stopped, the display on the first to fourth notification display devices 201 to 204 Therefore, it cannot be determined that the progress of the game is stopped. For this reason, the manager of the game hall looking at the base value displayed on the first to fourth notification display devices 201 to 204 may misunderstand that the progress of the game is not stopped. On the other hand, in the present embodiment, when the progress of the game is stopped, the display segments of the first to fourth notification display devices 201 to 204 are turned off. It is possible to easily determine that the progress of the game is stopped based on the states of the 4 notification display devices 201 to 204.

Further, in the present embodiment, when the progress of the game is stopped, in addition to the first to fourth notification display devices 201 to 204, the special figure display section 37a, the special figure hold display section 37b, The figure display section 38a and the general figure reservation display section 38b are also turned off. A special figure display part 37a, a special figure reservation display part 37b, a general figure display part 38a and a general figure reservation display which can be visually recognized from the outside without opening the gaming machine main body 12 to the outer frame 11 in front of the pachinko machine 10. By turning off the display segment of the portion 38b, it is possible to easily determine from the outside of the pachinko machine 10 that the progress of the game is stopped.

As already described in the forty-ninth embodiment, in the setting confirmation process (FIG. 166), it is set that the game stop flag is not set to “1” in the main process (FIG. 165) (step SB109: NO). It is executed as one condition. Therefore, "1" is not set in the game stop flag in the situation where the set value is being confirmed, and the processing of steps SI402 to SI415 is performed in the second timer interrupt processing (FIG. 281) executed in the situation. Is executed. Thereby, it is possible to perform the display indicating that the setting value is being confirmed and the display indicating the current setting value on the first to fourth notification display devices 201 to 204.

Further, as already described in the forty-ninth embodiment, the game stop flag is cleared to "0" by executing the initial setting at the start (step SB303) in the setting value update processing (FIG. 167). Therefore, "1" is not set in the game stop flag in the situation where the setting value is changed, and the processing of steps SI402 to SI415 is executed in the second timer interrupt processing (FIG. 281) executed in the situation. Is executed. Accordingly, it is possible to perform the display indicating that the setting value is being changed and the display indicating the current setting value on the first to fourth notification display devices 201 to 204.

Next, prior to the description of the configuration for executing the start waiting effect, the return command received by the sound-light side CPU 353 from the main side CPU 63 will be described. Similar to the forty-ninth embodiment, the main CPU 63 uses the normal recovery command, the update recovery command, and the confirmation command during the process (steps SB101 to SB122) at the start of supplying the operating power in the main process (FIG. 165). Either the return command of the above or the return command at the time of clearing is transmitted to the sound-light side CPU 353. In the present embodiment, when the sound-light side CPU 353 receives any return command, the start waiting state is entered. The details of the start waiting state will be described later.

As already described in the forty-ninth embodiment, the return command at the time of confirmation is sent to the pachinko machine 10 when the setting key insertion portion 68a is in the ON state without pressing the reset button 68c. When the supply of the operating power is started (that is, when the “setting confirmation operation” is performed at the start of the supply of the operating power), it is transmitted from the main CPU 63 to the sound/light side CPU 353. Specifically, when the reset button 68c is not pressed in the main process (FIG. 165) and the setting key insertion part 68a is turned on (step SB108: NO, step SB110: YES). Indicates that the power failure flag in the work area 221 for specific control is set to "1" (step SB104: YES), the checksum is normal (step SB105: YES), and the setting reference area 341 is normal. Range (step SB106: YES), the setting update display flag in the specific control work area 221 is not set to “1” (step SB107: NO), and the specific control work area 221 The setting confirmation process (step SB112) is executed on condition that "1" is not set in the game stop flag (step SB109: NO). In addition, in the main process (FIG. 165), in which the supply of the operating power is restarted after the supply of the operating power to the main CPU 63 is stopped in the situation where the setting confirmation process (step SB112) is executed, Even if the pachinko machine 10 is turned on without turning on the setting key insertion portion 68a (step SB110: NO), the setting confirmation display flag in the work area 221 for specific control is displayed. Based on that "1" is set (step SB111: YES), the setting confirmation process is executed (step SB112). Then, in step SB207 of the setting confirmation process (FIG. 166), a return command for confirmation is transmitted to the sound-light side CPU 353.

As already described in the forty-ninth embodiment, the return command at the time of updating supplies the operating power to the pachinko machine 10 in the ON state of the setting key insertion portion 68a and the pressing operation of the reset button 68c. Is started (that is, when the “setting change operation” is performed at the start of supplying the operating power), the main CPU 63 transmits the sound to the sound/light side CPU 353. Specifically, when the pressing operation of the reset button 68c and the ON operation of the setting key insertion portion 68a are performed in the main process (FIG. 165) (step SB108 or step SB120: YES, step SB114: YES), step SB115. The set value update processing (FIG. 167) is executed at. Then, in step SB314 of the setting value updating process (FIG. 167), a return command at the time of updating is transmitted to the sound-light side CPU 353.

As already described in the forty-ninth embodiment, the return command at the time of clear is sent to the pachinko machine 10 in a state where the reset button 68c is pressed without the ON operation of the setting key insertion part 68a being performed. When the supply of the operating power is started (that is, when the “RAM clear operation” is performed at the start of the supply of the operating power), the main CPU 63 transmits the sound to the sound/light side CPU 353. Specifically, when the reset button 68c is pressed in the main process (FIG. 165) (step SB108 or step SB120: YES) and the setting key insertion part 68a is not turned on (step SB114). : NO), the first RAM clearing process (step SB117) is executed on condition that the game stop flag is not set to "1" (step SB116: NO). Then, after the completion of the first RAM clearing process (step SB117), a clear return command is transmitted to the sound-light side CPU 353 (step SB118).

As already described in the forty-ninth embodiment, in the normal return command, the supply of operating power to the pachinko machine 10 is started without the ON operation of the setting key insertion portion 68a and the pressing operation of the reset button 68c being performed. In this case (that is, in the case of “no operation” at the time of starting the supply of operating power), the main CPU 63 transmits the sound power CPU 353. Specifically, in the main process (FIG. 165), when the pressing operation of the reset button 68c is not performed (step SB108: NO) and the ON operation of the setting key insertion portion 68a is not performed (step SB110: NO). ), the power failure flag is set to "1" (step SB104: YES), the checksum is normal (step SB105: YES), and the setting reference area 341 is in the normal range (step SB106). : YES), "1" is not set in the setting update display flag (step SB107: NO), "1" is not set in the game stop flag (step SB109: NO), and the confirmation display flag is set. On condition that "1" is not set (step SB111: NO), the normal recovery command is transmitted to the sound-light side CPU 353 (step SB113).

Next, a configuration for executing the start waiting effect will be described. As described above, after the supply of the operating power to the pachinko machine 10 is started, the sound-light side CPU 353 sends the normal return command, the update return command, the check return command and the clear return command from the main CPU 63. When either of them is received, the start waiting state is entered. The start waiting state ends when the sound-light side CPU 353 receives the variation command and the type command from the main CPU 63 and the game use effect (hereinafter, also referred to as “game use effect”) is started. .. Further, the start waiting state is also set in a case where a period in which neither the game turning effect nor the opening/closing execution mode effect is executed is a predetermined period (specifically, 10 minutes).

As a start waiting effect executed in the start waiting state, a demonstration effect in which a demo movie is displayed for 10 seconds on the symbol display device 41 (FIG. 3) and a next demonstration effect is started after the demonstration effect ends. In the meantime, there is a standby symbol display in which a symbol image for waiting for start is displayed on the symbol display device 41. In the demonstration effect and the standby symbol display, a common title background image including the title of the pachinko machine 10 is displayed. In the demonstration effect, a character moving image in which a predetermined character moves is displayed in front of the title background image. Further, in the standby symbol display, in front of the title background image, a stop symbol in which a predetermined combination of the left symbol image for waiting for start, the middle symbol image, and the right symbol image is stopped is displayed.

The demonstration effect performed in this embodiment is one type, and the standby symbol display performed in this embodiment is one type. In the start waiting state, the demonstration effect is started at the timing when the value of the timer counter 554a for starting a demo, which will be described later, becomes the maximum value. The timing at which the value of the demo start timer counter 554a reaches the maximum value is based on the timing at which the demo start timer counter 554a is updated after the demo start timer counter 554a is cleared to "0". It occurs every 15 seconds from the timing.

When both the condition of being in the start waiting state and the condition of the value of the timer counter 554a for demonstration start being the maximum value are satisfied, the demonstration effect is started in the symbol display device 41. If the condition of being in the start waiting state is not satisfied at the timing when the value of the demo start timer counter 554a reaches the maximum value, after the start waiting state is reached, the demo start timer is set in the start waiting state. The demonstration effect is started at the timing when the value of the counter 554a reaches the maximum value. When the demonstration effect is started in the start wait state, the symbol display device 41 repeatedly executes the demonstration effect for 10 seconds and the standby symbol display for 5 seconds until the start wait state ends.

When the supply of the operating power to the pachinko machine 10 is started, the sound-light side CPU 353 controls the display of the display control device 82 so that the pattern display device 41 displays the initial image and the model information image. The initial image is first displayed on the symbol display device 41. The initial image is an image in which all dots on the display surface 41a of the symbol display device 41 are in a light emitting state, and by confirming that the initial image is normally displayed on the symbol display device 41, the symbol display device 41 It can be confirmed that the liquid crystal display surface 41a is normal. After the initial image is displayed for a predetermined time (for example, 3 seconds), the display content of the symbol display device 41 is switched from the initial image to the model information image. The model information image is an image in which the manufacturer name and model name are displayed in the lower area of the pattern display device 41 so that the manufacturer name and model name of the pachinko machine 10 can be confirmed. The update notification indicating that the setting value update processing (FIG. 167) already described in the forty-ninth embodiment is being performed, and the setting confirmation processing (FIG. The confirmation notification indicating that 166) is being performed is performed in the area above the display of the manufacturer name and the model name. The details of the update notification and the confirmation notification will be described later.

In the pattern display device 41, in the situation where the model information image is displayed, it is in the start waiting state, and in the start waiting state, the value of the demo start timer counter 554a to be described later becomes the maximum value, so that the model information image is displayed. Ends and the demonstration production starts.

Prior to the description of the specific processing configuration for executing the demonstration effect and the standby symbol display, the storage area in the sound-light side RAM 355 will be described. FIG. 282 is an explanatory diagram for explaining a storage area in the sound-light side RAM 355. Note that the sound emission control board 351 (FIG. 172) in this embodiment is not provided with the RTC 356 (FIG. 172) and the RTC memory 357 (FIG. 172) in the 49th embodiment.

As shown in FIG. 282, in the sound-light side RAM 355 in the present embodiment, “0” is cleared and initial settings are made in the sound-light side RAM initialization processing (step SI509 of the sound-light side startup processing (FIG. 283)) described later. The non-initialization target area 554 excluded from the target and the initialization target area 555 set as the target of clearing “0” and initial setting in the sound-light-side RAM initialization processing are provided. The non-initialization target area 554 and the initialization target area 555 are storage areas to which the backup power is not supplied when the supply of the operating power to the pachinko machine 10 is stopped.

The non-initialization area 554 is provided with a timer counter 554a for starting a demo. The demo start timer counter 554a is a timer counter that enables the sound-light side CPU 353 to grasp the start timing of the demonstration effect in the start waiting state. The demonstration start timer counter 554a is incremented by 1 each time a sound light side timer interrupt process (FIG. 284) described later is executed, and reaches “0” after reaching a predetermined maximum value (specifically, 2999). It is a loop counter that returns to. In the sound-light timer interrupt process (FIG. 284), the process of updating the demo start timer counter 554a is executed regardless of whether or not it is in the start waiting state. The sound light side timer interrupt processing (FIG. 284) is executed at intervals of 5 milliseconds, and the demo start timer counter 554a reaches the maximum value at intervals of 15 seconds. As described above, in the start waiting state, the demonstration effect is started each time the value of the timer counter 554a for starting the demo reaches the maximum value. On the other hand, if the state is not in the start waiting state, the demonstration effect is not started even if the value of the timer counter 554a for starting the demo reaches the maximum value.

The initialization target area 555 is provided with a waiting state timer counter 555a and a waiting state flag 555b. The waiting state timer counter 555a indicates that the period during which neither the game turning effect nor the opening/closing execution mode effect is being executed becomes a predetermined period (specifically, 10 minutes) This is a timer counter that can be grasped by the CPU 353. The maximum value of the waiting state timer counter 555a is set to “120,000” in advance, and the waiting state timer counter 555a is in a state where the setting value is being confirmed, a state where the setting value is being changed, When none of the state in which the game reproduction effect is being executed, the state in the open/close execution mode, and the start waiting state is satisfied, 1 is added at 5 millisecond intervals and updated.

The waiting state flag 555b is a flag that enables the sound-light side CPU 353 to know that the start waiting state is set. The waiting state flag 555b is set to "1" when the sound-light side CPU 353 receives any one of the normal return command, the update return command, the confirmation return command and the clear return command. When the period during which neither the game turning effect nor the effect for opening/closing execution is executed becomes a predetermined period (specifically, 10 minutes) (the value of the waiting state timer counter 555a is the maximum value) If the value reaches (1), "1" is also set. Further, the waiting state flag 555b is cleared to "0" when the sound-light side CPU 353 receives the variation command and the type command from the main CPU 63 in the start waiting state and the game reproduction effect is started.

Next, a specific processing configuration for executing the demonstration effect and the standby symbol display will be described. First, the sound-light side startup processing executed by the sound-light side CPU 353 will be described with reference to the flowchart in FIG. 283. The sound-light side startup process is executed when the supply of operating power to the pachinko machine 10 is started.

In the sound-light side start-up process, first, a sound-light side RAM clear process is executed (step SI501). In the sound-light-side RAM clearing process, after the initialization non-initialization area 554 and the initialization target area 555 in the sound-light side RAM 355 are cleared to “0”, the initialization non-initialization area 554 and the initialization target area 555 are initialized. To do. As described above, when the supply of the operating power to the pachinko machine 10 is stopped, the backup power is not supplied to the non-initialization target area 554 and the initialization target area 555. Therefore, immediately after the supply of the operating power to the pachinko machine 10 is started, the storage areas of the non-initialization target area 554 and the initialization target area 555 are in an undefined state. By executing the sound-light side RAM clearing process in step SI501, the undefined state in the storage areas of the non-initialization target area 554 and the initialization target area 555 can be eliminated. After that, in the sound-light-side RAM clearing process, the display control of the display control device 82 is performed so that the initial image and the model information image are displayed on the symbol display device 41. As a result, the symbol display device 41 first starts displaying the initial image. As described above, after the initial image is displayed for a predetermined time (for example, 3 seconds), the display content of the symbol display device 41 is switched from the initial image to the model information image.

Then, "1" is set to the initialization flag provided in the initialization target area 555 of the sound-light side RAM 355 (step SI502). The initial setting flag indicates that after the operation power supply to the pachinko machine 10 is started and the sound/light side RAM clearing process (step SI501) is executed, one of the return commands (normal return command, update time) from the main CPU 63 is executed. This is a flag that enables the sound-light side CPU 353 to know that any of the return command of (1), the return command for confirmation, and the return command for clearing is not received. The initialization flag is cleared to "0" by receiving one of the return commands and executing the sound light side RAM initialization processing (step SI509) described later. While the initial setting flag is set to "1", in the sound/light side timer interrupt processing (FIG. 284) described later, processing for updating the demo start timer counter 554a (step SI601) is performed, while waiting. Processing for updating the state timer counter 555a (step SI603 to step SI621) is not performed. Therefore, in the situation where the setting value is being confirmed or the setting value is being changed, the start waiting state is prevented when the value of the waiting state timer counter 555a reaches the maximum value. As a result, the demonstration effect and the standby symbol display are prevented from being executed in the situation where the set value is confirmed or the set value is changed.

After that, the interruption of the sound light side timer interruption processing (FIG. 284) is permitted (step SI503). As a result, the process for updating the demo start timer counter 554a is executed. In the present embodiment, regardless of the presence or absence of the “setting change operation”, the “setting confirmation operation”, and the “RAM clear operation”, after the supply of the operating power to the pachinko machine 10 is started, the sound-light side CPU 353 is set to the main side. The demodulating timer counter is enabled by permitting the interrupt of the sound-light timer interrupt process (FIG. 284) prior to the process (the process after step SI504) performed based on the reception of any return command from the CPU 63. It is assumed that 554a is updated.

The period from the timing at which the supply of operating power to the pachinko machine 10 is started to the timing at which the demo start timer counter 554a is updated is not affected by external operations. Further, processing such as lottery for changing the period is not performed. For this reason, by starting the supply of operating power to a plurality of pachinko machines 10 at the same time, the demo start timer counters 554a in the plurality of pachinko machines 10 are updated at the same or substantially the same timing. You can

When the supply of operating power to a plurality of pachinko machines 10 is started simultaneously, for example, a plurality of pachinko machines 10 are installed in one island facility, and the power switches of the plurality of pachinko machines 10 are turned on. This is the case where the ON operation of the power supply device of the island facility is performed in the state of being. As already described in the first embodiment, the pachinko machine 10 is installed in the game hall by attaching and fixing the outer frame 11 to the island facility. A plurality of pachinko machines 10 can be installed in the island facility. The island equipment includes a power supply device (not shown), and by turning on the power supply device of the island equipment, it becomes possible to supply operating power to the pachinko machine 10 installed in the island equipment. When the power supply device of the island facility is turned off, the supply of operating power to the pachinko machine 10 installed in the island facility is stopped. The supply of operating power to the pachinko machine 10 installed in the island equipment is started when both the power switch of the pachinko machine 10 and the power supply device of the island equipment are turned on. Therefore, when the power switch of the plurality of pachinko machines 10 installed in the island equipment is turned on, the power supply device of the island equipment is turned on, so that the plurality of pachinko machines 10 installed in the island equipment are operated. The supply of operating power to the pachinko machines 10 can be started all at once.

Returning to the description of the sound-light side startup processing (FIG. 283), after permitting the interrupt of the sound-light side timer interrupt processing (FIG. 284) in step SI503, in steps SI504 to SI508, the above-mentioned forty-ninth embodiment is executed. The same processing as steps SB401 to SB405 in the effect control processing (FIG. 173) is executed. Specifically, when the update start command is received from the main CPU 63 (step SI504: YES), the update notification setting process is executed (step SI505). The update start command is transmitted to the sound/light side CPU 353 when the set value update processing (FIG. 167) is started by the main side CPU 63. In the update notification setting process, an image showing that the set value update process (FIG. 167) is being executed, an image for making it possible to recognize the operation content for changing the set value, and the set value update process ( Display control of the display control device 82 is performed so that an image for making it possible to recognize the operation content for ending (FIG. 167) is displayed on the symbol display device 41. In the present embodiment, these images are displayed in the area above the display of the manufacturer name and the model name in the model information image, in the manner that they are present in front of the model information image. This allows the manager of the game hall to recognize that the setting value is being changed, and the operation content and the setting value update process necessary to change the setting value (FIG. 167). It becomes possible for the manager of the game hall to recognize the operation content necessary for ending the game. In addition to or instead of the above-mentioned notification being performed by the symbol display device 41, at least one of the display light emitting unit 53 and the speaker unit 54 may be configured.

When the confirmation start command is received from the main CPU 63 (step SI506: YES), the confirmation notification setting process is executed (step SI507). The confirmation start command is transmitted to the sound/light side CPU 353 when the setting confirmation process (FIG. 166) is started by the main CPU 63. In the confirmation notification setting process, an image showing that the setting confirmation process (FIG. 166) is being executed and an image for making it possible to recognize the operation content for terminating the setting confirmation process (FIG. 166) are displayed. The display control device 82 controls the display so that it is displayed on the symbol display device 41. In the present embodiment, these images are displayed in the area above the display of the manufacturer name and the model name in the model information image, in the manner that they are present in front of the model information image. This allows the manager of the game hall to recognize that the current setting value of the pachinko machine 10 is being confirmed, and is necessary for ending the setting confirmation process (FIG. 166). It is possible for the manager of the game hall to recognize various operation contents. In addition to or instead of the above-mentioned notification being performed by the symbol display device 41, at least one of the display light emitting unit 53 and the speaker unit 54 may be configured.

When the processes of steps SI504 to SI507 are executed, it is determined whether any of the normal restoration command, the clear restoration command, the confirmation restoration command, and the update restoration command are received from the main CPU 63 ( Step SI508). As described above, the normal recovery command is executed in the main process (FIG. 165) by all of the setting confirmation process (step SB112), the set value update process (step SB115), and the first RAM clear process (step SB117). When the process at the start of supplying the operating power (steps SB101 to SB122) ends without any processing, the information is transmitted in step SB113. The clear return command is transmitted in step SB118 when the first RAM clear process is completed in step SB117 of the main process (FIG. 165) as described above. The return command upon confirmation is transmitted to the sound/light side CPU 353 in step SB207 of the setting confirmation process (FIG. 166). The return command at the time of updating is transmitted to the sound/light side CPU 353 in step SB314 of the setting value updating process (FIG. 167).

If these return commands have not been received (step SI508: NO), the process returns to step SI504. The sound-light side CPU 353 does not execute the processing after step SI509 until any of the return commands is received. As a result, while the main CPU 63 is executing the processing (step SB101 to step SB122) at the time of starting the supply of operating power, the sound/light side CPU 353 can be prevented from starting the execution control of the normal effect. It will be possible. Further, as already described, "1" is set to the initialization flag of the initialization target area 555 until any of the return commands is received and the sound-light side RAM initialization processing (step SI509) is executed. Since the state is not released, the process for updating the wait state timer counter 555a is not executed. Therefore, the start waiting state does not occur when the value of the waiting state timer counter 555a reaches the maximum value.

In the present embodiment, in step SI503, which is prior to the processing of step SI504 to step SI508, the interruption of the sound light side timer interrupt processing (FIG. 284) described later is permitted, and the demonstration start timer counter 554a is enabled. Start the update. Therefore, during the period from the timing when the supply of the operating power to the pachinko machine 10 is started to the timing when the update of the demonstration start timer counter 554a is started, the sound-light side CPU 353 sends any return command from the main side CPU 63. Is not affected by the timing of receiving the. This prevents the timing of starting the update of the demo start timer counter 554a from being shifted due to the presence/absence of the “setting confirmation operation”, the “setting change operation”, and the “RAM clear operation”. The value of the demo start timer counter 554a is cleared to "0" in the sound/light side RAM clear processing (step SI501) before the update of the demo start timer counter 554a is started. For this reason, the timing at which the value of the demo start timer counter 554a reaches the maximum value (specifically, 2999) is deviated depending on the presence or absence of the "setting confirmation operation", the "setting change operation", and the "RAM clear operation". Is prevented.

As already described in the forty-ninth embodiment, the setting confirmation process (FIG. 166) and the setting value update process (FIG. 167) switch the setting key insertion part 68a from the ON state to the OFF state using the setting key. It ends when the operation is performed. Since the end timings of the setting confirmation process (FIG. 166) and the setting value update process (FIG. 167) change depending on the timing of the human operation (operation by the manager of the game hall), the operating power of the pachinko machine 10 is changed. During the period from the start of the supply until the sound-light side CPU 353 receives the return command for confirmation or the return command for update, the sound-light side CPU 353 normally operates after the supply of the operating power to the pachinko machine 10 is started. The period is different from the period until the return command or the return command at the time of clear is received.

In the configuration in which the update start timing of the demo start timer counter 554a changes depending on the timing at which the sound-light side CPU 353 receives one of the return commands from the main side CPU 63, the plurality of pachinko machines 10 operate simultaneously. When starting the supply of electric power and performing the “setting confirmation operation” or the “setting change operation” for some of the plurality of pachinko machines 10 at the time of starting the supply of the operating power, In the pachinko machine 10 on which the "setting confirmation operation" or the "setting change operation" has been performed, the timing when the value of the demo start timer counter 554a reaches the maximum value, and the "setting confirmation operation" or the "setting change operation" has not been performed. In the pachinko machine 10, the timing at which the value of the timer counter 554a for starting the demo reaches the maximum value is deviated. As already described, the demonstration effect is started at the timing when the value of the timer counter 554a for starting the demonstration reaches the maximum value in the start waiting state. Therefore, the timing at which the value of the demo start timer counter 554a reaches the maximum value deviates, so that the timing at which the demonstration effect starts in the start waiting state deviates. In this case, the pachinko machine 10 for which the “setting confirmation operation” or the “setting change operation” has been performed may be easily identified based on the start timing of the demonstration effect. The set value is a value corresponding to the player's advantage, and as described above in the first embodiment, the higher the set value, the higher the advantage. Based on the start timing of the demonstration effect, the pachinko machine 10 for which the “setting confirmation operation” for confirming the setting value corresponding to the player's advantage or the “setting change operation” for changing the setting value is performed is specified. The problem is that it gets easier.

On the other hand, the timing at which the demo start timer counter 554a is updated in the present embodiment is not affected by the timing at which the sound-light side CPU 353 receives any return command from the main CPU 63. Therefore, it is possible to prevent the timing at which the value of the demo start timer counter 554a reaches the maximum value from deviating due to the presence/absence of the “setting confirmation operation” and the “setting change operation”, and in the start waiting state. It is possible to prevent the start timing of the demonstration effect from being shifted. This prevents the pachinko machine 10 for which the “setting confirmation operation” or the “setting change operation” has been performed based on the start timing of the demonstration effect from being easily identified.

When any return command is received from the main CPU 63 (step SI508: YES), the sound/light side RAM initialization processing is executed (step SI509). In the sound-light-side RAM initialization processing, the initialization target area 555 in the sound-light side RAM 355 is cleared to “0” and initialized, while the non-initialization area 554 in the sound-light side RAM 355 is cleared to “0” and initialized. Does not. In the sound-light side RAM initialization processing in step SI509, when the update time notification is being performed when the initialization target area 555 is cleared to “0” and the initialization is performed, the update time notification is ended and the confirmation time notification is performed. If the above is performed, the confirmation notification is ended. On the other hand, even if the sound-light-side RAM initialization process is executed, the display of the model information image on the symbol display device 41 is not completed. The model information image continues to be displayed on the symbol display device 41 until the demonstration effect is started. The initialization flag is cleared to "0" by clearing "0" and initializing the initialization target area 555. As a result, the processing in steps SI603 to SI621 is executed in the sound light side timer interrupt processing (FIG. 284) described later.

On the other hand, in the sound-light-side RAM initialization processing in step SI509, "0" is not cleared and the initialization of the non-initialization area 554 is not performed, so even if the sound-light-side RAM initialization processing is executed, it is not initialized. The value of the timer counter 554a for starting the demonstration in the area 554 is not cleared to "0". This prevents the timing at which the value of the demo start timer counter 554a reaches the maximum value (specifically, 2999) from being deviated in accordance with the timing at which the sound-light side RAM initialization processing in step SI509 is executed. ing.

After that, the waiting state flag 555b in the initialization target area 555 is set to "1" to enter the waiting state (step SI510). As already described, the demonstration effect is started in the symbol display device 41 by the value of the timer counter 554a for starting the demo reaching the maximum value (specifically, 2999) in the start waiting state.

Thereafter, if the return command received from the main CPU 63 is the normal return command (step SI511: YES), the normal return notification setting process is executed (step SI512). In the normal return notification setting process, neither the setting confirmation process (step SB112), the set value update process (step SB115) nor the first RAM clear process (step SB117) is executed in the main process (FIG. 165). The display control device 82 is display-controlled so that an image showing that the process (step SB101 to step SB122) at the time of starting the supply of the operating power is finished is displayed on the symbol display device 41. In the present embodiment, the image is displayed in the area above the display of the maker name and the model name in the model information image, in the form of being present in front of the model information image. As a result, the process at the start of supply of operating power (step SB101 to step 101) is performed without executing any of the setting confirmation process (step SB112), the set value update process (step SB115), and the first RAM clear process (step SB117). It becomes possible for the manager of the game hall to recognize that step SB122) has ended. In addition to or instead of the above-mentioned notification being performed by the symbol display device 41, at least one of the display light emitting unit 53 and the speaker unit 54 may be configured.

When a negative determination is made in step SI511, it is determined whether or not the return command received from the main CPU 63 is the update return command (step SI513), and the update return command is received. In this case (step SI513: YES), the post-update notification setting process is executed (step SI514). In the post-update notification setting process, the display control device 82 is display-controlled so that the image indicating that the set value update process (FIG. 167) has been executed is displayed on the symbol display device 41. In the present embodiment, the image is displayed in the area above the display of the maker name and the model name in the model information image, in the form of being present in front of the model information image. This allows the manager of the game hall to recognize that the setting value updating process has been completed. In addition to or instead of the above-mentioned notification being performed by the symbol display device 41, at least one of the display light emitting unit 53 and the speaker unit 54 may be configured.

When a negative determination is made in step SI513, it is determined whether or not the return command received from the main CPU 63 is the confirmation return command (step SI515), and the confirmation return command is received. In this case (step SI515: YES), the post-confirmation notification setting process is executed (step SI516). In the post-confirmation notification setting process, the display control device 82 is display-controlled so that an image indicating that the setting confirmation process (FIG. 166) has been executed is displayed on the symbol display device 41. In the present embodiment, the image is displayed in the area above the display of the maker name and the model name in the model information image, in the form of being present in front of the model information image. This allows the manager of the game hall to recognize that the setting confirmation process has been completed. In addition to or instead of the above-mentioned notification being performed by the symbol display device 41, at least one of the display light emitting unit 53 and the speaker unit 54 may be configured.

If a negative determination is made in step SI511, step SI513, and step SI515, it means that the return command received from the main CPU 63 is the return command at the time of clearing, so the clear return notification setting process is executed. (Step SI517), the real-light/light-side start-up process ends. In the clear return notification setting process, the display control device 82 is controlled so that the image indicating that the first RAM clear process (step SB117 of the main process (FIG. 165)) has been executed is displayed on the symbol display device 41. To do. In the present embodiment, the image is displayed in the area above the display of the maker name and the model name in the model information image, in the form of being present in front of the model information image. This allows the manager of the game hall to recognize that the first RAM clearing process has been completed. In addition to or instead of the above-mentioned notification being performed by the symbol display device 41, at least one of the display light emitting unit 53 and the speaker unit 54 may be configured.

Next, the sound-light side timer interrupt processing executed by the sound-light side CPU 353 will be described with reference to the flowchart in FIG. The sound-light side timer interrupt process is repeatedly executed in a relatively short cycle (for example, 5 milliseconds) after the interrupt is permitted in step SI503 of the sound-light side start-up process (FIG. 283).

In the sound light side timer interrupt process, first, the process of updating the timer counter 554a for starting the demonstration is executed (step SI601). In the update process of the demo start timer counter 554a, 1 is added to the value of the demo start timer counter 554a, and when the value of the demo start timer counter 554a after adding 1 is “3001”, the demo start timer counter 554a is started. The value of the timer counter 554a is cleared to "0".

Then, it is determined whether or not "1" is set in the initialization flag in the initialization target area 555 (step SI602). As described above, after the supply of operating power to the pachinko machine 10 is started and the sound light side RAM clear processing (step SI501 of the sound light side startup processing (FIG. 283)) is executed, the initialization flag is set to The sound-light side CPU 353 can understand that no return command (any one of a normal return command, an update return command, a check return command and a clear return command) is received from the main CPU 63. Is a flag. When the initial setting flag is set to "1" (step SI602: YES), the sound light side timer interrupt processing is ended without executing the processing of steps SI603 to SI621.

On the other hand, when "1" is not set in the initial setting flag (step SI602: NO), it is determined whether or not an opening command is received from the main CPU 63 (step SI603). As already described in the first embodiment, in the opening command, the processing for starting the opening period in the opening/closing execution mode of this time has not yet been performed in the special electric power starting processing (step S409 of the special electric power control processing (FIG. 12)). When it is not executed, it is transmitted from the main CPU 63.

When the opening command is received (step SI603: YES), the effect setting process for the opening/closing execution mode is executed (step SI604). In the effect setting process for the opening/closing execution mode, the data table for the opening/closing execution mode is read from the sound-light side ROM 354 to the initialization target area 555 of the sound-light side RAM 355. Then, the light emission control of the display light emitting unit 53 and the sound output control of the speaker unit 54 are executed according to the data table. As a result, the effect for the open/close execution mode is executed in the display light emitting unit 53 and the speaker unit 54. Further, the opening command is transmitted to the display control device 82. Upon receiving the opening command, the display control device 82 controls the display of the symbol display device 41 so that the display effect for the opening/closing execution mode is executed.

After that, the opening/closing execution mode effect flag provided in the initialization target area 555 is set to "1" (step SI605). The opening/closing execution mode effect flag is a flag for the CPU 353 to specify that the effect for the opening/closing execution mode is being executed.

When a negative determination is made in step SI603 or when the processing of step SI605 is executed, it is determined whether or not an ending command is received from the main CPU 63 (step SI606). As already described in the first embodiment, the ending command is not yet processed for starting the ending period in the current open/close execution mode in the special electric power termination processing (step S412 of the special electric power control processing (FIG. 12)). When it is not executed, it is transmitted from the main CPU 63.

When the ending command is received (step SI606: YES), the ending effect setting process is executed (step SI607). In the ending effect setting process, the ending data table is read from the sound-light side ROM 354 to the initialization target area 555 of the sound-light side RAM 355. Then, the light emission control of the display light emitting unit 53 and the sound output control of the speaker unit 54 are executed according to the data table. As a result, the effect of the ending period is executed in the display light emitting unit 53 and the speaker unit 54. Further, the ending command is transmitted to the display control device 82. By receiving the ending command, the display control device 82 controls the display of the symbol display device 41 so that the display effect of the ending period is executed.

If a negative determination is made in step SI606, or if the processing of step SI607 is executed, it is determined whether or not the variation command and the type command have been received from the main CPU 63 (step SI608). As already described in the first embodiment, the variation command and the type command are transmitted from the main CPU 63 in step S512 of the special figure variation start process (FIG. 13).

When the variation command and the type command are received (step SI608: YES), it is determined whether "1" is set in the waiting state flag 555b in the initialization target area 555 (step SI609). When "1" is set to the waiting state flag 555b (step SI609: YES), the ending process of the start waiting effect is executed (step SI610). In the end process of the start waiting effect, the process for ending the demonstration effect is executed when the demonstration effect is executed, and the standby symbol display is ended when the standby symbol display is executed. Execute the process.

After that, the waiting state flag 555b in the initialization target area 555 is cleared to "0" to end the start waiting state (step SI611). Then, the start waiting effect flag provided in the initialization target area 555 is cleared to "0" (step SI612). The start waiting effect flag is a flag that enables the sound-light side CPU 353 to grasp that either the demonstration effect or the standby symbol display is being executed as the start waiting effect.

In this way, when the sound-light side CPU 353 receives the variation command and the type command from the main CPU 63 in the start waiting state, the start waiting effect (demo effect and standby symbol display) is ended, and the start waiting state is finish.

If a negative determination is made in step SI609, or if the process of step SI612 is executed, the game time effect setting process is executed (step SI613). In the game turn effect setting process, the data table for executing the game turn effect corresponding to the variation command and the type command received this time is read from the sound-light side ROM 354 to the initialization target area 555 of the sound-light side RAM 355. .. Then, the light emission control of the display light emitting unit 53 and the sound output control of the speaker unit 54 are executed according to the data table. As a result, the game diverting effect is executed in the display light emitting unit 53 and the speaker unit 54. Further, the game-time production effect command corresponding to the variation command and the type command received this time is transmitted to the display control device 82. The display control device 82 controls the display of the symbol display device 41 so that the game turn effect corresponding to the variation command and the type command received this time is executed by receiving the game turn effect command. As already described in the first embodiment, in the game turning effect, the variable display of the symbol is displayed on the symbol display device 41, and when the game turning effect ends, the special figure variation start process (FIG. 13). The combination of symbols corresponding to the result of the hit/no hit determination process (step S504) and the distribution determination process (step S506) is stopped and displayed.

When the sound-light side CPU 353 receives the variation command and the type command in the situation where the demonstration effect is being performed, the symbol display device 41 displays the character moving image in which the predetermined character operates in front of the title background image described above. The state (the state in which the demonstration effect is performed) is switched to the state in which the game-purpose effect corresponding to the variation command and the type command received this time is being executed. Further, when the sound-light side CPU 353 receives the variation command and the type command in the situation where the standby symbol display is being performed, the symbol display device 41 waits for a predetermined start in front of the title background image described above. The combination of the left symbol image, the middle symbol image and the right symbol image is stopped. From the state where the stop symbol is displayed (the state where the standby symbol is displayed), the variation command and the type command received this time The game diversion effect corresponding to is switched to a state in which it is being executed.

Then, "1" is set to the game reproduction effect flag provided in the initialization target area 555 (step SI614). The game turning effect flag is a flag that enables the sound-light side CPU 353 to know that the game turning effect is being executed.

If a negative determination is made in step SI608, or if the process of step SI614 is performed, the effect update process is executed (step SI615). In the effect update process, when the effect for the opening/closing execution mode is being executed, the process for updating the effect for the opening/closing execution mode is executed, and when the game turning effect is being executed. A process for updating the game diversion effect is executed.

After that, it is determined whether or not the effect for the opening/closing execution mode is completed in the effect updating process in step SI615 (step SI616), and when the effect for the opening/closing execution mode is completed (step SI616: YES), initialization is performed. The opening/closing execution mode effect flag in the target area 555 is cleared to "0" (step SI617).

When a negative determination is made in step SI616, it is determined whether or not the game reproductive effect is completed in the effect renewal process in step SI615 (step SI618), and when the game reproducible effect is completed (step SI618). : YES), the game-use effect flag in the initialization target area 555 is cleared to "0" (step SI619).

When the process of step SI617 is performed or the process of step SI619 is performed, the wait state timer counter 555a in the initialization target area 555 is cleared to "0" (step SI620). As described above, the waiting state timer counter 555a has a predetermined period (specifically, 10 minutes) during which neither the game turning effect nor the opening/closing execution mode effect is executed. This is a timer counter that enables the sound-light-side CPU 353 to know that. When the value of the waiting state timer counter 555a reaches a predetermined maximum value (specifically, 120,000), the start waiting state is entered. When the production for the open/close execution mode is finished and the production for game play is finished, by clearing the waiting state timer counter 555a to “0”, the timing at which the production for the open/close execution mode is finished or the production for game play From the timing when is finished, it is possible to start counting the period in which neither the effect for the opening/closing execution mode nor the game-use effect is executed.

If a negative determination is made in step SI618, or if the process of step SI620 is performed, the start waiting effect process is executed (step SI621), and the main light side timer interrupt process is ended. FIG. 285 is a flowchart showing the start waiting effect process.

In the start waiting effect process, first, referring to the states of the opening/closing execution mode effect flag and the game turning effect flag in the initialization target area 555, it is determined whether the opening/closing execution mode effect or the game turning effect is being executed. Is determined (step SI701). When the effect for the opening/closing execution mode or the game-use effect is being executed (step SI701: YES), the process for step S702 to step SI712 is not executed, and the main start waiting effect process is directly ended.

On the other hand, when the effect for the open/close execution mode and the effect for game play are not executed (step SI701: NO), it is determined whether the waiting state flag 555b in the initialization target area 555 is set to "1". The determination is made (step SI702). If "1" is not set in the waiting state flag 555b (step SI702: NO), that is, if the starting waiting state is not set, the value of the waiting state timer counter 555a in the initialization target area 555 is incremented by 1 (step SI703), it is determined whether or not the value of the wait state timer counter 555a after adding 1 is the maximum value (specifically, 120,000) (step SI704). As already described, the value of the waiting state timer counter 555a is cleared to "0" at the timing when the effect for the opening/closing execution mode or the game-time effect is finished. When an affirmative determination is made in step SI704, the state in which neither the effect for opening/closing execution mode nor the effect for game play is being executed for a predetermined period (specifically, 10 minutes). Since it means that the process is continued, the wait state flag 555b in the initialization target area 555 is set to "1" to start the start wait state (step SI705).

If an affirmative determination is made in step SI702 or if the processing of step SI705 is performed, it is determined whether or not "1" is set in the start waiting effect flag in the initialization target area 555 (step SI706. ). As described above, the start waiting effect flag is a flag that allows the sound-light side CPU 353 to know that either the demonstration effect or the standby symbol display is being executed as the start waiting effect. When "1" is not set in the start waiting effect flag (step SI706: NO), the value of the demo start timer counter 554a in the non-initialization area 554 is the maximum value (specifically, 2999). It is determined whether or not (step SI707). If the value of the demo start timer counter 554a is not the maximum value (step SI707: NO), the main start waiting effect process is terminated without starting the demo effect.

On the other hand, if the value of the demo start timer counter 554a is the maximum value (step SI707: YES), the start waiting effect flag is set to "1" (step SI708), and the demonstration effect start setting process is executed. (Step SI709), the process for production for waiting for this start is ended. In the start setting process of the demonstration effect in step SI709, when the value of the timer counter 554a for demonstration start becomes the maximum value (specifically, 2999) in the situation where the standby symbol display is performed (in step SI712 described later). If a positive determination is made), it is also executed. In the start setting process of the demonstration effect, when the model information image is being displayed on the symbol display device 41, the display control device 82 is controlled so that the display of the model information image is ended, and the symbol is also controlled. When the standby symbol display is being executed on the display device 41, the display control device 82 is controlled so that the standby symbol display ends. Then, the display control of the display control device 82 is performed so that the symbol display device 41 executes the demonstration effect. Note that the light emission control of the display light emitting unit 53 may be executed so that the display light emitting unit 53 emits light in the light emitting mode for the demonstration effect, and the speaker unit 54 outputs the sound so that the sound output for the demonstration effect is performed. It may be configured to control.

If a positive determination is made in step SI706, that is, if the start waiting effect (demo effect and standby symbol display) is already being executed, the value of the timer counter 554a for starting a demo in the non-initialization area 554 is " It is determined whether or not it is "1999" (step SI710). If the value of the demo start timer counter 554a is "1999" (step SI710: YES), it means that the demonstration effect has been executed for 10 seconds and the end timing of the demonstration effect has come. The start designing process of the standby symbol display is executed (step SI711), and the process for waiting start production is ended. In the standby symbol display start setting process in step SI711, the display control device 82 is controlled so that the demonstration effect executed in the symbol display device 41 ends and the standby symbol display in the symbol display device 41 starts. .. Note that the light emission control of the display light emitting unit 53 may be executed so that the display light emitting unit 53 emits light in the light emitting mode for displaying the standby symbol, and the speaker unit 54 is used so that the sound output for the standby symbol display is performed. It may be configured to control the sound output.

When a negative determination is made in step SI710, it is determined whether or not the value of the demonstration start timer counter 554a in the non-initialization area 554 is the maximum value "2999" (step SI712). If the value of the demonstration start timer counter 554a is not the maximum value (specifically, 2999) (step SI712: NO), the main start waiting effect process is ended as it is. On the other hand, when the value of the timer counter 554a for starting the demonstration is the maximum value (specifically, 2999) (step SI712: YES), 15 seconds have elapsed from the start timing of the previous demonstration effect and a new demonstration effect is produced. Since it means that it is the start timing of, the start setting process of the demonstration effect in step SI709 is executed, and the process for the start waiting effect is ended. As a result, the standby symbol display is ended on the symbol display device 41 and a new demonstration effect is started.

Next, with reference to the time chart of FIG. 286, the manner in which the demonstration effect is executed after the supply of the operating power to the pachinko machine 10 is started will be described. 286(a) shows the execution period of the demonstration effect, FIG. 286(b) shows the execution period of the standby symbol display, and FIG. 286(c) shows the value of the timer counter 554a for the demonstration start in the non-initialization area 554. Shows the timing of reaching the maximum value, FIG. 286(d) shows the clear timing of the demo start timer counter 554a, and FIG. 286(e) shows the sound/light side RAM clear by the sound/light side startup processing (FIG. 283). 286 (f) shows the timing at which the sound light side RAM initialization processing (step SI 509) is executed at the sound light side start-up processing (FIG. 283). FIG. 286(g) shows the state of the waiting state flag 555b in the initialization target area 555, FIG. 286(h) shows the state where the set value is being updated, and FIG. 286(i) shows the pachinko machine 10. The timing at which the supply of operating power is started.

First, a case where the “setting confirmation operation”, the “setting change operation”, and the “RAM clear operation” are not performed when the supply of the operating power to the pachinko machine 10 is started will be described.

When the supply of operating power to the pachinko machine 10 is started at the timing of t1 without turning on the setting key insertion portion 68a and pressing the reset button 68c as shown in FIG. At this timing, as shown in FIG. 286(e), the sound-light side RAM clearing process (step SI501 of the sound-light side startup process (FIG. 283)) is executed. As described above, in the sound light side RAM clear processing, “0” is cleared and the initial setting of the non-initialization area 554 and the initialization target area 555 of the sound light side RAM 355 is performed. Therefore, at the timing of t1, as shown in FIG. 286(d), the value of the demo start timer counter 554a in the non-initialization area 554 is cleared to "0". Then, the interruption of the sound-light side timer interruption processing (FIG. 284) is permitted, so that the updating of the demonstration start timer counter 554a is started.

After that, at the timing t2 when the sound-light side CPU 353 receives the normal return command from the main-side CPU 63, as shown in FIG. 286(f), the sound-light side RAM initialization process (sound light side startup process (FIG. 283)) is performed. Step SI509) is executed. The non-initialization target area 554 provided with the demonstration start timer counter 554a is excluded from the target of “0” clearing and initial setting in the sound-light side RAM initialization processing, and thus, as shown in FIG. 286(d). At the timing of t2, the demo start timer counter 554a is not cleared to "0". At the timing of t2, as shown in FIG. 286(g), the waiting state flag 555b is set to "1", and the start waiting state is entered.

After that, at the timing of t3, which is approximately 15 seconds after the timing of t1 when the supply of the operating power to the pachinko machine 10 is started, the value of the demo start timer counter 554a is the maximum value as shown in FIG. 286(c). (Specifically 2999). As shown in FIG. 286(g), since the pachinko machine 10 is in the start waiting state at the timing of t3, as shown in FIG. 286(a), the demonstration effect is started on the symbol display device 41 at the timing of t3. ..

Then, 10 seconds after the timing of t3, the demonstration effect is finished at the timing of t4 as shown in FIG. 286(a), and the standby symbol display is started at the symbol display device 41 as shown in FIG. 286(b). It Then, when the value of the demo start timer counter 554a reaches the maximum value (specifically, 2999) as shown in FIG. 286(c) at the timing of t5, which is 15 seconds after the timing of t3, as shown in FIG. 286(b). ), the standby symbol display ends, and the demonstration effect is started on the symbol display device 41 as shown in FIG. 286(a).

As described above, when the supply of the operating power to the pachinko machine 10 is started without performing the “setting confirmation operation”, the “setting change operation” and the “RAM clear operation”, the sound/light side RAM clear processing (sound/light After the side start-up process (step SI501 of FIG. 283) is executed and the demo start timer counter 554a is cleared to “0”, updating of the demo start timer counter 554a is started. From the timing at which the supply of operating power to the pachinko machine 10 is started (timing at t1) to the timing at which the value of the demo start timer counter 554a first reaches the maximum value (timing at t3), there is no external operation. Not affected. Further, processing such as lottery for changing the period is not performed. Therefore, by simultaneously starting to supply the operating power to the plurality of pachinko machines 10, the value of the demo start timer counter 554a in each of the plurality of pachinko machines 10 first reaches the maximum value (specifically, 2999). The timings to reach can be the same or substantially the same.

In the symbol display device 41, the first demonstration effect is started approximately 15 seconds after the supply of the operating power to the pachinko machine 10 is started. In the sound-light side RAM initialization processing (step SI509 of the sound-light side start-up processing (FIG. 283)) executed by the sound-light side CPU 353 upon receiving the normal recovery command from the main CPU 63, the value of the timer counter 554a for starting the demo Is not cleared to "0", the timing at which the sound-light side CPU 353 receives the normal return command does not affect the timing at which the demonstration effect is started.

As already described, when the “RAM clear processing” is performed and the supply of operating power to the pachinko machine 10 is started, the sound-light side CPU 353 replaces the normal return command from the main side CPU 63 with a return command at the time of clearing. However, the value of the timer counter 554a for starting the demo is still in the sound-light-side RAM initialization processing (step SI509 of the sound-light-side start-up processing (FIG. 283)) executed by receiving the return command at the time of clearing. "0" is not cleared. Therefore, the timing at which the sound-light side CPU 353 receives the return command at the time of clearing does not affect the timing at which the demonstration effect is started. This prevents the timing at which the value of the demo start timer counter 554a reaches the maximum value from changing depending on the presence or absence of the "RAM clear operation", and also changes the start timing of the demonstration effect. It is prevented. The case where the “setting confirmation operation” or the “setting change operation” is performed and the supply of operating power to the pachinko machine 10 is started will be described later.

The demonstration effect is started every time the timer counter 554a for starting the demonstration reaches the maximum value (specifically, 2999) in the start waiting state, and the symbol display device 41 displays the demonstration effect for 10 seconds and the standby symbol display for 5 seconds. And are repeatedly executed until the start waiting state ends.

Next, a case will be described in which the supply of operating power is started while the setting key insertion portion 68a is turned on and the reset button 68c is pressed (that is, the “setting change operation” is performed).

As shown in FIG. 286(i), when the setting key insertion portion 68a is turned on and the reset button 68c is pressed to start the supply of the operating power at the timing of t6, the timing of FIG. As shown in e), the sound light side RAM clear processing (step SI501 of the sound light side start-up processing (FIG. 283)) is executed. As a result, the value of the demo start timer counter 554a is cleared to "0" as shown in FIG. 286(d). Then, the interruption of the sound-light side timer interruption processing (FIG. 284) is permitted, so that the updating of the demonstration start timer counter 554a is started. Further, as shown in FIG. 286(h), the set value is updated at the timing of t6.

Thereafter, as shown in FIG. 286(c), the value of the timer counter 554a for demonstrating the maximum value ( Specifically, it reaches 2999). As shown in FIG. 286(g), at the timing of t7, the waiting state flag 555b in the initialization target area 555 is not set to "1", and the pachinko machine 10 is not in the waiting state for start. Therefore, even if the value of the demonstration start timer counter 554a reaches the maximum value, the demonstration effect is not started at the timing of t7 as shown in FIG. 286(a).

Then, when the state in which the setting value is updated as shown in FIG. 286(h) ends at the timing of t8, the sound-light side CPU 353 receives the update return command from the main side CPU 63. As a result, the sound light side RAM initialization processing (step SI509 of the sound light side start-up processing (FIG. 283)) is executed at the timing of t8 as shown in FIG. 286(f). The non-initialization target area 554 provided with the demonstration start timer counter 554a is excluded from the target of “0” clearing and initial setting in the sound-light side RAM initialization processing, and thus, as shown in FIG. 286(d). At the timing of t8, the demo start timer counter 554a is not cleared to "0". At the timing of t8, as shown in FIG. 286(g), the waiting state flag 555b is set to "1", and the start waiting state is entered.

Thereafter, the value of the demo start timer counter 554a reaches the maximum value (specifically 2999) at the timing of t9, which is 15 seconds after the timing of t7, as shown in FIG. 286(c). As shown in FIG. 286(g), since the pachinko machine 10 is in the start waiting state at the timing of t9, the demonstration effect is started on the symbol display device 41 at the timing of t9 as shown in FIG. 286(a). ..

As described above, when the “setting change operation” is performed and the set value is updated at the time of starting the supply of the operating power to the pachinko machine 10, the demonstration start timer counter 554a in the situation where the set value is changed. The value of may reach the maximum value (specifically, 2999). Further, when the "setting confirmation operation" is performed and the setting value is confirmed at the time of starting the supply of the operating power to the pachinko machine 10, the demonstration start timer counter 554a in the situation where the setting value is confirmed. The value of may reach the maximum value (specifically, 2999). Since the pachinko machine 10 is not in the start waiting state while the setting value is being confirmed or changed, the value of the demo start timer counter 554a reaches the maximum value in the situation where the setting value is being confirmed or changed. Even if you do, the demonstration production will not start.

When the “setting change operation” is performed to change the set value at the start of supplying the operating power to the pachinko machine 10, the main CPU 63 does not send the update return command until the change of the set value is completed. Therefore, the execution timing of the sound-light side RAM initialization process (step SI509 of the sound-light side start-up process (FIG. 283)) executed when the sound-light side CPU 353 receives the update return command changes the set value. Varies depending on the length of time that is done. Further, when the “setting confirmation operation” is performed and the setting value is confirmed at the time of starting the supply of the operating power to the pachinko machine 10, the main CPU 63 transmits a return command at the time of confirmation until the confirmation of the setting value is completed. do not do. Therefore, the execution timing of the sound-light side RAM initialization process (step SI509 of the sound-light side start-up process (FIG. 283)) performed when the sound-light side CPU 353 receives the return command for confirmation is to confirm the set value. Varies depending on the length of time that is done. In the present embodiment, the value of the demo start timer counter 554a is not cleared to "0" even if the sound-light-side RAM initialization process is executed. Therefore, the sound-light-side CPU 353 has a return command at the time of update or a return at the time of confirmation. The timing of receiving the command does not affect the timing of starting the demonstration effect. This prevents the timing at which the value of the demo start timer counter 554a reaches the maximum value from changing depending on the presence/absence of the "setting confirmation operation" and the "setting change operation", and also the start timing of the demonstration effect. It is prevented from changing.

Next, referring to the time chart of FIG. 287, after a preset period (specifically, 10 minutes) is set in a state in which neither the opening/closing execution mode effect nor the game turning effect is being executed. The manner in which the demonstration production is started will be described. 287(a) shows the execution period of the demonstration effect, FIG. 287(b) shows the timing when the value of the timer counter 554a for starting the demo in the non-initialization area 554 reaches the maximum value, and FIG. 287(c) shows The state of the waiting state flag 555b in the initialization target area 555 is shown, FIG. 287(d) shows the execution period of the game reproduction effect, and FIG. The timing to receive the type command is shown.

When the sound-light side CPU 353 receives the variation command and the type command as shown in FIG. 287(e) at the timing of t1 when the demonstration effect is being executed on the symbol display device 41 in the start waiting state, FIG. 287(a) ), the demonstration effect is finished in the symbol display device 41, and as shown in FIG. 287(c), the waiting state flag 555b in the initialization target area 555 is cleared to “0” and the start waiting state is finished. Then, at the timing of t1, as shown in FIG. 287(d), the game light effect is started in the display light emitting unit 53, the speaker unit 54, and the symbol display device 41.

After that, at the timing of t2, the value of the demo start timer counter 554a in the non-initialization area 554 reaches the maximum value (specifically, 2999) as shown in FIG. 287(b). As shown in FIG. 287(c), the wait state flag 555b is not set to "1" at the timing of t2, and the pachinko machine 10 is not in the start waiting state. Therefore, even if the value of the demonstration start timer counter 554a reaches the maximum value, the demonstration effect is not started at the timing of t2 as shown in FIG. 287(a).

After that, at the timing of t3, as shown in FIG. 287(d), the game reproductive effect ends. After that, at the timing of t4, the value of the timer counter 554a for starting the demo reaches the maximum value (specifically, 2999) as shown in FIG. 287(b). As shown in FIG. 287(c), since the waiting state flag 555b is not set to "1" at the timing of t4 and the pachinko machine 10 is not in the waiting state for starting, the value of the timer counter 554a for starting the demo is maximum. Even if the value is reached, the demonstration effect is not started as shown in FIG. 287(a).

After that, when the state in which the game reproducibility is not executed is continued until the timing of t5 when 10 minutes have passed from the timing of t3, the waiting state flag 555b is set to "1" at the timing of t5 as shown in FIG. 287(c). Will be set and the system will be in a standby state. Even in the start waiting state, the condition that the value of the demo start timer counter 554a reaches the maximum value (specifically, 2999) is not satisfied at the timing of t5, as shown in FIG. 287(a). The demonstration production will not start.

Then, when the value of the demo start timer counter 554a reaches the maximum value (specifically, 2999) as shown in FIG. 287(b) at the timing of t6 which is the start waiting state, as shown in FIG. 287(a). At the timing of t6, the demonstration effect is started on the symbol display device 41.

As described above, the demonstration effect is started when the value of the timer counter 554a for starting the demo reaches the maximum value (specifically, 2999) in the start waiting state. The demo start timer counter 554a is updated by supplying operating power to the pachinko machine 10 after the interruption of the sound-light side timer interrupt processing (FIG. 284) is permitted in step SI503 of the sound-light side startup processing (FIG. 283). Until the game is stopped, it is executed regardless of the presence/absence of the effect for the opening/closing execution mode and the effect for game play. Therefore, after the supply of the operating power to the pachinko machine 10 is started, the value of the demonstration start timer counter 554a is the maximum value depending on the execution timing, the execution period, and the number of executions of the effect for the opening/closing execution mode and the effect for game use. It is possible to prevent the timing of reaching to change.

When the supply of operating power to a plurality of pachinko machines 10 is started at the same time, the execution timing, execution period, and number of executions of the opening and closing execution mode effect and the game inversion effect that are subsequently performed in each pachinko machine 10 are different. Even when the plurality of pachinko machines 10 enter the same state, the timing at which the value of the timer counter 554a for starting the demo reaches the maximum value (specifically, 2999) can be the same or substantially the same, and In the pachinko machine 10, the timing for starting the demonstration effect can be the same or substantially the same.

According to this embodiment described in detail above, the following excellent effects are exhibited.

When the game stop flag is set to "1" and the progress of the game is stopped, new display data is not provided to the fifth display circuit 265. The display segments of the display devices 201 to 204 are turned off. If the display of the base value is continued on the first to fourth notification display devices 201 to 204 even when the progress of the game is stopped, from the display on the first to fourth notification display devices 201 to 204. Cannot determine that the progress of the game has been stopped, and the administrator of the game hall who has seen the display of the base value may misunderstand that the progress of the game is not stopped. On the other hand, when the progress of the game is stopped, the display segments of the first to fourth notification display devices 201 to 204 are turned off, whereby the first to fourth notifications are performed. It is possible to easily determine that the progress of the game is stopped based on the states of the display devices 201 to 204 for use.

When the progress of the game is stopped, new display data is not provided to the first to fourth display circuits 261 to 264. The special segment display section 37a, the special figure reservation display section 37b, the general figure display section 38a, and the display segment of the general figure reservation display section 38b display segments when new display data is no longer provided to the corresponding display circuits 261 to 264. It goes off. In addition to the first to fourth notification display devices 201 to 204, a special figure display portion 37a that can be visually recognized from the outside without opening the gaming machine body 12 to the front of the pachinko machine 10 with respect to the outer frame 11, The figure hold display section 37b, the figure hold display section 38a, and the figure hold display section 38b are also turned off so that it is possible to easily determine from the outside of the pachinko machine 10 that the progress of the game is stopped. It can be possible.

When the progress of the game is stopped, the state where new display data is not provided to the first to fifth display circuits 261 to 265 is maintained until the state is released. Therefore, until the state where the progress of the game is stopped is released, the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, the general figure reservation display unit 38b, and the first to fourth notifications. The off state of the display segments of the display devices 201 to 204 can be continued. This makes it easy to understand that the progress of the game has been stopped.

The normal ball management process (FIG. 74) is executed even after the game stop flag is set to "1" and the progress of the game is stopped. As a result, the normal out counter 231e can count the number of game balls discharged from the game area PA after the game stop flag is set to "1", and the progress of the game is stopped. After that, it becomes possible to calculate a base value that reflects the number of game balls discharged from the game area PA.

The operation from the outside is not affected during the period from the timing when the supply of the operating power to the pachinko machine 10 is started to the timing when the value of the demo start timer counter 554a first reaches the maximum value (specifically, 2999). Further, processing such as lottery for changing the period is not performed. Therefore, by simultaneously starting the supply of operating power to a plurality of pachinko machines 10, the timing at which the value of the demo start timer counter 554a first reaches the maximum value in the plurality of pachinko machines 10 is the same or substantially the same. Can be arranged as Further, after the interruption of the sound and light side timer interruption process (FIG. 284) is permitted, the value of the timer counter 554a for demonstrating the start and end of the pachinko game regardless of whether or not the effect for the opening/closing execution mode and the effect for game play are executed. It is updated each time the sound/light side timer interrupt process (FIG. 284) is executed until the supply of operating power to the machine 10 is stopped. Accordingly, by simultaneously supplying the operating power to the plurality of pachinko machines 10, the demo start timer counter 554a of the plurality of pachinko machines 10 is stopped until the supply of the operating power to the pachinko machines 10 is stopped. It is possible to arrange the timings at which the values reach the maximum value to be the same or substantially the same, and to arrange the timings at which the demonstration effects are started in the plurality of pachinko machines 10. By simultaneously starting the demonstration effects on the plurality of pachinko machines 10, it is possible to give a sense of unity to the demonstration effects on the plurality of pachinko machines 10 and increase the player's interest in the pachinko machines 10.

The demonstration effect is started when the value of the timer counter 554a for starting the demonstration reaches the maximum value (specifically, 2999) in the start waiting state. After the supply of the operating power to the pachinko machine 10 is started, the sound/light side start-up processing (FIG. 283) is executed based on the sound/light side CPU 353 receiving one of the return commands from the main CPU 63. The interrupt of the sound-light side timer interrupt process (FIG. 284) is permitted prior to the process (process after step SI504) and the update of the demo start timer counter 554a is started. Therefore, it is possible to prevent the timing at which the value of the demo start timer counter 554a reaches the maximum value from changing depending on the presence/absence of the “setting confirmation operation”, the “setting change operation”, and the “RAM clear operation”. As a result, the timing at which the value of the demo start timer counter 554a reaches the maximum value in the plurality of pachinko machines 10 by simultaneously starting the supply of operating power to the plurality of pachinko machines 10 becomes the same or substantially the same timing. In addition to being able to align, it is possible to align the timing at which the demonstration effect starts with the same or substantially the same timing.

In the sound-light side RAM initialization process (step SI509 of the sound-light side start-up process (FIG. 283)) executed when the sound-light side CPU 353 receives one of the return commands, the value of the timer counter 554a for starting the demo Is not cleared to "0". Therefore, it is possible to prevent the timing at which the value of the demo start timer counter 554a reaches the maximum value from changing depending on the presence/absence of the “setting confirmation operation”, the “setting change operation”, and the “RAM clear operation”. The start timing of the demonstration production is prevented from changing.

In the configuration in which the timing at which the value of the demo start timer counter 554a reaches the maximum value changes depending on the presence or absence of the “setting confirmation operation”, the “setting change operation”, and the “RAM clear operation”, a plurality of pachinko machines 10 can be used. When the supply of the operating power is started at the same time, and when the supply of the operating power is started, a “setting confirmation operation”, a “setting change operation”, and a “RAM” are performed on some of the plurality of pachinko machines 10. When any of the "clear operation" is performed, the timing at which the demonstration effect is started in the pachinko machine 10 for which the "setting confirmation operation", the "setting change operation", or the "RAM clear operation" has been performed, and the "setting confirmation operation" , "Setting change operation" and "RAM clear operation" are not performed, there is a deviation from the timing at which the demonstration effect is started in the pachinko machine 10. In this case, the pachinko machine 10 for which the “setting confirmation operation”, the “setting change operation”, or the “RAM clear operation” has been performed based on the start timing of the demonstration effect may be easily identified. On the other hand, in the present embodiment, the timing at which the value of the demo start timer counter 554a reaches the maximum value does not change depending on the presence/absence of the “setting confirmation operation”, the “setting change operation”, and the “RAM clear operation”. Thus, it is possible to prevent the pachinko machine 10 on which any one of the “setting confirmation operation”, the “setting change operation”, and the “RAM clear operation” has been performed based on the start timing of the demonstration effect from being specified.

The configuration is such that the value of the demo start timer counter 554a reaches the maximum value at a predetermined interval (specifically, every 15 seconds) after the sound and light side timer interrupt processing (FIG. 284) is enabled, and When the value of the timer counter 554a for starting the demo reaches the maximum value, the demonstration effect is started. The demonstration start timer counter 554a is updated every time the sound/light side timer interrupt processing (FIG. 284) is executed regardless of whether or not it is in the start waiting state. Therefore, the start timing of the demonstration effect when the start waiting state is restarted after the start waiting state is once released by the execution of the opening/closing execution mode effect and the game turning effect is It is possible to prevent deviation from the start timing of the demonstration effect when it is not canceled. As a result, when the start timings of the demonstration effects in the plurality of pachinko machines 10 are aligned, the execution timing, execution period, and number of executions of the effect for the open/close execution mode and the game time effect are different in each pachinko machine 10 thereafter. Even if this happens, it is possible to prevent the timing of starting the demonstration effect from being shifted in the start waiting state in the plurality of pachinko machines 10.

The sound light side RAM clear processing (step SI501 of the sound light side start-up processing (FIG. 283)) is executed based on the start of the supply of the operating power to the pachinko machine 10, and at the same time, one of the main side CPU 63 The sound-light-side RAM initialization processing (step SI509) is executed based on the reception of the return command of (1). In the sound-light side RAM clear processing, “0” is cleared and the initial setting is performed for the non-initialization target area 554 and the initialization target area 555 in the sound-light side RAM 355. As a result, after the supply of the operating power is started, it is possible to eliminate the indefinite state of the information in the non-initialization target area 554 and the initialization target area 555 early. On the other hand, in the sound-light-side RAM initialization processing, only the initialization target area 555 is cleared to “0” and the initialization is performed, and the non-initialization target area 554 provided with the demonstration start timer counter 554a is cleared to “0”. And no initialization is done. This prevents the timing at which the value of the demo start timer counter 554a reaches the maximum value from being deviated due to the presence/absence of the “setting confirmation operation”, the “setting change operation”, and the “RAM clear operation”. It is prevented that the start timing of the effect is shifted.

The period in which the display data provided to the first to fifth display circuits 261 to 265 is stored and held is not limited to the predetermined period (for example, 16 milliseconds), and the first to fifth display The display data provided to the circuits 261 to 265 may be stored and held until the supply of operating power to the display circuits 261 to 265 is stopped. In this configuration, if the game stop flag is set to "1" in step SI303 of the fraud detection process (FIG. 280(b)), or if the game stop corresponding flag is not set to "1" in step SI304. If determined, the process for transmitting the display data of all “0” is executed to all of the first to fifth display circuits 261 to 265, and step SI402 to the second timer interrupt process (FIG. 281). The processing of step SI415 is prevented from being executed. Thereby, from the state where the progress of the game is stopped until the state is released, the special figure display portion 37a, the special figure hold display portion 37b, the general figure display portion 38a, the general figure hold display portion 38b. Also, the display segments of the first to fourth notification display devices 201 to 204 can be turned off.

Further, the management process (FIG. 70) is not limited to the configuration executed in step SI220 of the first timer interrupt process (FIG. 279), and the management process is executed after step SB125 of the main process (FIG. 165). It may be configured to be executed in the residual process repeatedly executed in. Even with this configuration, it is possible to prevent the management process from being stopped when the game stop flag is set to "1" and the progress of the game is stopped. In this configuration, the update timing counter is provided in the work area 221 for specific control. The update of the update timing counter is executed in the first timer interrupt process (FIG. 279) regardless of the states of the game stop flag and the in-progress process flag. When the update timing counter is updated and it is time to update the display contents of the first to fourth notification display devices 201 to 204, the update timing flag provided in the specific control work area 221 is set. Set "1". In the display process (FIG. 131) executed in the management process (FIG. 70), the state of the update timing flag in the work area 221 for specific control is referred to, and the update timing flag is set to “1”. When the display contents of the first to fourth notification display devices 201 to 204 are updated, the timing is updated. Accordingly, even if the management process is executed in the residual process that is executed irregularly, the display contents of the first to fourth notification display devices 201 to 204 can be updated periodically.

Further, based on the fact that the game stop flag is set to "1", the special figure display portion 37a, the special figure hold display portion 37b, and the general figure display are displayed together with the display segments of the first to fourth notification display devices 201 to 204. The configuration is not limited to the configuration in which the display segments of the unit 38a and the universal figure reservation display unit 38b are turned off, and only the display segments of the first to fourth notification display devices 201 to 204 are turned off. The display unit 37a, the special figure reservation display section 37b, the general figure display section 38a, and the general figure reservation display section 38b may be configured to continue the display. Specifically, when "1" is set to the game stop flag, the processing of steps SI403 to SI408 in the second timer interrupt processing (FIG. 281) is stopped. Further, in the type counter update process (step SI411), if the game stop flag is set to "1", after adding "1" to the value of the type counter in the work area 221 for specific control, the addition When the value of the subsequent type counter becomes "5", "1" is set in the type counter. In this case, new display data is provided to the first to fourth display circuits 261-264, but new display data is not provided to the fifth display circuit 265. Thereby, while continuing the display in the special figure display part 37a, the special figure reservation display part 37b, the general figure display part 38a, and the general figure reservation display part 38b, for the display of the 1st-4th notification display devices 201-204. Only the segment can be turned off.

In addition, based on the fact that the game stop flag is set to "1", the first to third characters are displayed together with the display segments of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a and the general figure reservation display unit 38b. The configuration is not limited to the configuration in which the display segments of the fourth notification display devices 201 to 204 are turned off, and the special figure display unit 37a, the special figure hold display unit 37b, the general figure display unit 38a, and the general figure hold display are provided. The display segment of the portion 38b may be turned off, and the display on the first to fourth notification display devices 201 to 204 may be continued. Specifically, when the game stop flag is set to "1", in the type counter update process (step SI411 of the second interrupt process (FIG. 281)), the type counter in the work area 221 for specific control is set to " Set only 5”. In this case, new display data is provided to the fifth display circuit 265, but new display data is not provided to the first to fourth display circuits 261 to 264. Thereby, while continuing the display on the 1st-4th notification display devices 201-204, for the display of the special figure display part 37a, the special figure reservation display part 37b, the general figure display part 38a, and the general figure reservation display part 38b. The segment can be turned off.

Further, the game stop flag is not limited to the configuration in which the display segments of the first to fourth notification display devices 201 to 204 are turned off based on the fact that "1" is set in the game stop flag. The display corresponding to the state in which the progress of the game is stopped may be performed on the first to fourth notification display devices 201 to 204 based on the setting of "1" to. For example, as a display corresponding to the state where the progress of the game is stopped, all the display segments in the first to fourth notification display devices 201 to 204 are displayed in a blinking manner (first to fourth notification display device). In all of 201 to 204, “8” may be displayed blinking. Specifically, display data (first to fourth notification display devices 201 to 201) in the fifth display data buffer 275 for setting all display segments of the first to fourth notification display devices 201 to 204 in a lighting state. Display data for displaying "8" on all of 204 is set. Then, the display data and the type data indicating that the display data corresponds to the fifth display circuit 265 are transmitted to the display IC 266 for a predetermined lighting period (for example, 0.5 seconds). At the same time, the display data and the type data are prevented from being transmitted to the display IC 266 for a predetermined turn-off period (for example, 0.5 seconds). By alternately repeating the predetermined lighting period and the predetermined extinguishing period, all the display segments in the first to fourth notification display devices 201 to 204 are blinked and displayed, and the game progresses. It is possible to let the manager of the game hall understand that the game is stopped. As a display corresponding to the state where the progress of the game is stopped, a part of the display segments of the first to fourth notification display devices 201 to 204 may be displayed in a blinking manner. All the display segments in the notification display devices 201 to 204 may be lit and displayed. It is easy to understand that the progress of the game is stopped by configuring the display corresponding to the state where the progress of the game is stopped on the first to fourth notification display devices 201 to 204. Can be one.

Also, based on the fact that the game stop flag is set to "1", the display segments of the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a and the general figure reservation display unit 38b are turned off. The configuration is not limited to this, and the special figure display portion 37a, the special figure reservation display portion 37b, the general figure display portion 38a, and the general figure reservation display portion 38b are set based on the fact that "1" is set in the game stop flag. The display corresponding to the state in which the progress of the game is stopped may be performed. Even with this configuration, it can be easily understood that the progress of the game is stopped.

When the game stop flag is set to "1", the interrupt of the second timer interrupt process (Fig. 281) is prohibited, and the game stop flag is cleared to "0". In this case, the second timer interrupt process (FIG. 281) may be configured to perform the process of permitting the interrupt. Even with this configuration, in the state where the progress of the game is stopped, the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, the general figure reservation display unit 38b, and the first to fourth notification display devices 201. The display segments of ~ 204 can be turned off, and when the state where the progress of the game is stopped is canceled, the special figure display section 37a, the special figure hold display section 37b, the general figure display section 38a, the general figure display section 38a, It is possible to start the display on the figure hold display unit 38b and the first to fourth notification display devices 201 to 204.

Further, when the supply of operating power to the pachinko machine 10 is stopped, backup power for storing and holding information in the sound/light side RAM 355 may be supplied for a predetermined backup period (for example, 10 seconds). Good. Specifically, in the sound light side RAM clear processing (step SI501 of the sound light side start-up processing (FIG. 283)) executed based on the start of the supply of the operation power to the pachinko machine 10, the operation power is Of the sound power side RAM 355 is in an indefinite state because the period from the stop of the supply of the operating power to the restart of the supply of the operating power exceeds the above-described predetermined backup period (for example, 10 seconds). In this case, "0" is cleared in all the storage areas of the sound-light side RAM 355 and the initial setting is performed. In this case, the demonstration start timer counter 554a is cleared to "0" in the sound/light side RAM clearing process. After that, as in the 77th embodiment, the sound light side timer interrupt processing (FIG. 284) interrupt is permitted in step SI503) of the sound light side start-up processing (FIG. 283), and the demonstration start timer counter 554a. Will be updated. Therefore, by simultaneously starting the supply of the operating power to the plurality of pachinko machines 10 for which the above-mentioned predetermined backup period has elapsed since the supply of the operating power was stopped, the same as in the 77th embodiment described above. Moreover, in the plurality of pachinko machines 10, the timing at which the value of the demo start timer counter 554a reaches the maximum value can be aligned, and the timing at which the demonstration effect is started in the start waiting state can be aligned.

On the other hand, if the period from the stop of the supply of the operating power to the restart of the supply of the operating power is within the predetermined backup period and the information of the sound/light side RAM 355 is stored and held, the demonstration The start timer counter 554a is excluded from the target of clearing “0” and initial setting in the sound/light side RAM clearing process (step SI501 of the sound/light side starting process (FIG. 283)). Therefore, in a situation where the start timings of the demonstration effects are aligned in the plurality of pachinko machines 10, the supply of operating power is individually stopped for some of the plurality of pachinko machines 10 while the operation power is individually stopped. Immediately after that (before the above-mentioned predetermined backup period elapses), perform the operation to restart the supply of operating power while performing the "setting confirmation operation", "setting change operation" or "RAM clear operation". It is possible to restart the update of the demo start timer counter 554a while avoiding the value of the start timer counter 554a being cleared to "0". By avoiding that the value of the demo start timer counter 554a is cleared to “0”, it is possible to prevent the timing at which the value of the demo start timer counter 554a reaches the maximum value from being deviated and to start it. It is possible to prevent the timing of starting the demonstration effect from deviating in the waiting state. As a result, there is a possibility that the pachinko machine 10 for which the “setting confirmation operation”, the “setting change operation”, or the “RAM clear operation” has been individually performed after the supply of the operating power is simultaneously started may be easily identified. It can be reduced.

Further, a configuration may be adopted in which backup power for storing and holding information in the sound/light side RAM 355 is supplied in a state where the supply of operating power to the pachinko machine 10 is stopped. Specifically, as already described in the 77th embodiment, the demonstration effect is started at the timing when the value of the timer counter 554a for starting the demonstration reaches the maximum value in the start waiting state. Even in the start waiting state, the start of the demonstration effect is on standby until the value of the demo start timer counter 554a reaches the maximum value. The demo-start timer counter 554a in this configuration is a step of the sound-light side RAM clearing process (sound-light side startup process (FIG. 283)) that is executed based on the start of supply of operating power to the pachinko machine 10. In SI501), it is excluded from the target of clearing “0” and initial setting. Since the information in the sound/light side RAM 355 is stored and held even when the supply of the operating power to the pachinko machine 10 is stopped, the demonstration start timer counter 554a becomes in an indefinite state immediately after the supply of the operating power is started. Not not. As already described in the 77th embodiment, after the sound-light side RAM clearing process is executed, the sound-light side timer interrupt process (FIG. 284) is enabled to start updating the demo start timer counter 554a. To be done. After that, in this configuration, when the sound-light side CPU 353 receives the normal recovery command from the main-side CPU 63, the sound-light side first RAM initialization processing is executed. In the sound-light-side first RAM initialization processing, the value of the demo start timer counter 554a is cleared to "0". When the supply of operating power is started at the same time without performing the “setting confirmation operation”, the “setting change operation” and the “RAM clear operation” to the plurality of pachinko machines 10, the sound and light are emitted from the plurality of pachinko machines 10. The timing at which the side first RAM initialization processing is executed is aligned, and the timing at which the value of the demo start timer counter 554a is cleared to “0” is aligned. As described above, since the interruption of the sound light side timer interrupt processing (FIG. 284) is permitted before the sound light side first RAM initialization processing is executed, the sound light side first RAM initialization processing is executed. By arranging the timings to be adjusted, the timings at which the values of the demo start timer counters 554a reach the maximum values can be aligned in the plurality of pachinko machines 10 and the start timings of the demonstration effects in the start waiting state can be aligned.

On the other hand, in the present configuration, when the sound-light side CPU 353 receives a return command for confirmation, a return command for updating, or a return command for clearing from the main CPU 63, the sound-side second RAM initialization process is executed. .. The demonstration start timer counter 554a is excluded from the target of “0” clearing and initialization in the sound/light side second RAM initialization process, and the demo start timer counter 554a is executed even if the sound/light side second RAM initialization process is performed. The value of 554a is not cleared to "0". In a situation where the start timings of the demonstration effects are aligned in the plurality of pachinko machines 10, the supply of operating power is individually stopped for some of the plurality of pachinko machines 10 and immediately after that. If the operation power supply is restarted while performing the “setting confirmation operation”, the “setting change operation”, or the “RAM clear operation”, the sound/light side RAM is based on the start of the operation power supply. The clear process is executed, and thereafter, the sound-light-side second RAM initialization process is executed based on receipt of a return command for confirmation, a return command for update, or a return command for clear from the main CPU 63. It As described above, the value of the demo start timer counter 554a is not cleared to "0" even if the sound light side RAM clear processing and the sound light side second RAM initialization processing are executed. Therefore, in the pachinko machine 10 in which the "setting confirmation operation", the "setting change operation", or the "RAM clear operation" is individually performed after the supply of the operating power to the plurality of pachinko machines 10 is started at the same time. When the value of the demo start timer counter 554a reaches the maximum value and the value of the demo start timer counter 554a in the pachinko machine 10 in which the "setting confirmation operation", the "setting change operation" and the "RAM clear operation" have not been performed The deviation from the timing at which the maximum value reaches is suppressed. This reduces the possibility that the pachinko machine 10 for which the “setting confirmation operation”, the “setting change operation”, or the “RAM clear operation” has been individually performed can be easily identified based on the start timing of the demonstration effect. It becomes possible to do.

Further, backup power for storing and holding information in the sound/light side RAM 355 is supplied in a state where the supply of the operating power to the pachinko machine 10 is stopped, and a demonstration is started when the supply of the operating power to the pachinko machine 10 is started. The value of the timer counter 554a for use may not be cleared to "0". Specifically, the demonstration start timer counter 554a uses the sound-light side RAM clearing process (step SI501 of the sound-light side start-up process (FIG. 283)) and the sound-light side RAM initialization process (sound-light side start-up process ( It is excluded from the targets for clearing "0" in step SI509) of FIG. 283). In the configuration in which the backup power is not supplied to the sound/light side RAM 355 when the supply of the operation power to the pachinko machine 10 is stopped, the storage area of the sound/light side RAM 355 is indefinite immediately after the supply of the operation power to the pachinko machine 10 is started. Since it is in the state, the sound-light side RAM clear processing (step SI501 of the sound-light side startup processing (FIG. 283)) clears all the storage areas of the sound-light side RAM 355 to “0” and performs the initial setting. There is a need. On the other hand, in this configuration, the backup power is supplied to the sound-light side RAM 355 in a state where the supply of the operating power to the pachinko machine 10 is stopped, so that the sound is generated immediately after the supply of the operating power to the pachinko machine 10 is started. The storage area of the light side RAM 355 does not become indefinite. For this reason, when the supply of the operating power to the pachinko machine 10 is started, the sound light side RAM clearing process (step SI501 of the sound light side start-up process (FIG. 283)) and the sound light side RAM initialization process (sound light side) are performed. The demo start timer counter 554a was stored in the demo start timer counter 554a when the supply of operating power to the pachinko machine 10 was stopped without clearing the demo start timer counter 554a to "0" in step SI509 of the side startup processing (FIG. 283). The update of the timer counter 554a for starting the demo can be restarted from the value.

As already described in the 77th embodiment, the demonstration effect is started at the timing when the value of the timer counter 554a for starting the demonstration reaches the maximum value in the start waiting state. Even in the start waiting state, the start of the demonstration effect is on standby until the value of the demo start timer counter 554a reaches the maximum value. In this configuration, when the values stored in the demonstration start timer counter 554a at the time of the supply stop of the previous operation power in the plurality of pachinko machines 10 are different, the operation power is supplied to the plurality of pachinko machines 10 on the day. Even if all of the pachinko machines 10 are simultaneously started, the timings at which the value of the demo start timer counter 554a reaches the maximum value in the plurality of pachinko machines are different timings, and the timings at which the demonstration effects are started in the start waiting state are different timings. Becomes By adopting a configuration in which the update mode of the past timer timer 554a for starting the demonstration is reflected in the start timing of the demonstration effect, "setting confirmation operation", "setting change operation", or It is possible to prevent the pachinko machine 10 on which the “RAM clear operation” is performed from being easily identified.

Further, the configuration is not limited to the configuration in which the time interval that is the start timing of the demonstration effect in the start waiting state is constant, and there is a plurality of types of time intervals that are the start timing of the demonstration effect in the start waiting state. Good. Specifically, the sound-light-side ROM 354 stores in advance a maximum value table in which a plurality of maximum values of the timer counter 554a for starting the demonstration are set. "2999" is set as the maximum value of the demo start timer counter 554a in the pointer information of "0" in the maximum value table, and "2999" is set as the maximum value of the demo start timer counter 554a in the pointer information of "1". "3999" is set, and "4999" is set in the pointer information of "2" as the maximum value of the demonstration start timer counter 554a. Further, the non-initialization area 554 is provided with a maximum value counter that enables the sound-light side CPU 353 to grasp the maximum value of the demonstration start timer counter 554a.

In the sound light side start-up process (FIG. 283), when the interruption of the sound light side timer interrupt process (FIG. 284) is permitted in step SI503, the maximum value table is stored in the non-initialization area 554 from the sound light side ROM 354. read out. Then, the numerical value information of "2999" set in the pointer information of "0" in the maximum value table is set in the maximum value counter in the non-initialization area 554 as the maximum value of the timer counter 554a for starting the demo. In the update process of the demo start timer counter 554a (step SI601 of the sound-light timer interrupt process (FIG. 284)), the update process (step SI601) is executed with the maximum value of the demo start timer counter 554a. When the value of the timer counter 554a for starting the demonstration is cleared to "0", the pointer information in the maximum value table is updated. Specifically, 1 is added to the current pointer information, and when the pointer information after the addition of 1 becomes "3", the pointer information is cleared to "0". Then, the numerical value information (numerical value information of “2999”, “3999”, or “4999”) set in the updated pointer information is set as a new maximum value of the demonstration start timer counter 554a and the non-initialization area 554 is set. Set to the maximum value counter in. As a result, the maximum value of the timer counter 554a for starting the demonstration is updated.

In the update process of the demo start timer counter 554a (step SI601 of the sound-light side timer interrupt process (FIG. 284)), the pointer information in the maximum value table is updated in a manner interlocking with the update of the demo start timer counter 554a. .. Therefore, by simultaneously supplying the operating power to the plurality of pachinko machines 10 and arranging the timings at which the values of the demo start timer counters 554a reach the maximum values, the maximum value tables of the plurality of pachinko machines 10 are displayed. The update timing of the pointer information can be aligned. This makes it possible to align the start timings of the demonstration effects in the plurality of pachinko machines 10 while setting a plurality of types of time intervals that are the start timings of the demonstration effects in the start waiting state.

<78th Embodiment>
This embodiment is different from the 77th embodiment in the configuration for grasping the timing of starting the demonstration effect in the start waiting state. The configuration different from that of the 77th embodiment will be described below. Note that the description of the same configuration as the 77th embodiment is basically omitted.

In the present embodiment, the RTC 356 (FIG. 172) and the RTC memory 357 (FIG. 172) are mounted on the sound emission control board 351 (FIG. 172) as in the forty-ninth embodiment. As already described in the forty-ninth embodiment, the RTC 356 is a real-time clock, constantly measures date information and time information, and according to an instruction from the sound-light side CPU 353, the measured date information and The configuration is capable of outputting time information (also referred to as date and time information). The RTC 356 is provided with a backup power supply, and it is possible to measure the date information and the time information even while the pachinko machine 10 is powered off. Note that the RTC 356 is not limited to the configuration in which the date and time information is measured, and may have a configuration in which only the time information is measured.

Further, as already described in the forty-ninth embodiment, the RTC memory 357 is a memory (that is, a volatile storage means) such as an SRAM and a DRAM that requires external power supply to retain the storage, and is used for both reading and writing. Used. The RTC memory 357 stores date and time information of the RTC 356 in accordance with an instruction from the sound-light side CPU 353. The date and time information stored in the RTC memory 357 is read by the sound-light side CPU 353 as necessary. The RTC memory 357 is configured to be supplied with backup power from a backup power supply provided for the RTC 356, and the date and time information is stored and retained even while the pachinko machine 10 is powered off. However, the present invention is not limited to this, and the RTC memory 357 may be an EEPROM or the like that does not require external power supply to store and hold information.

The sound-light side RAM 355 in this embodiment is not provided with the non-initialization target area 554 and the initialization target area 555 in the 77th embodiment. In the sound/light side RAM clear processing (step SI801) and the sound/light side RAM initialization processing (step SI808) in the sound/light side startup processing (FIG. 288) described later, all the storage areas of the sound/light side RAM 355 are “0”. It is the target of clearing and initial setting.

The sound-light-side RAM 355 is not provided with the demonstration start timer counter 554a in the 77th embodiment. In the present embodiment, the date and time information is acquired from the RTC 356 after the operating power to the pachinko machine 10 is started, and the acquired date and time information is stored in the RTC memory 357 as the reference time information for the demonstration effect. In the start waiting state, when the difference between the reference information of the demonstration effect stored in the RTC memory 357 and the current date and time information in the RTC 356 becomes an integer multiple of a predetermined time (specifically 15 seconds), the symbol The demonstration effect is started on the display device 41.

FIG. 288 is a flowchart showing the sound-light side startup processing executed by the sound-light side CPU 353 in this embodiment. The sound-light side startup process is executed when the supply of operating power to the pachinko machine 10 is started.

In step SI801, a sound-light side RAM clearing process is executed (step SI801). As described above, in the sound-light side RAM clearing process, “0” of the sound-light side RAM 355 is cleared and the initial setting is performed. When the supply of the operating power to the pachinko machine 10 is stopped, the backup power is not supplied to the sound/light side RAM 355. Therefore, immediately after the supply of the operating power to the pachinko machine 10 is started, the storage area of the sound/light side RAM 355 is in an indefinite state. By executing the sound-light side RAM clearing process in step SI801, the indefinite state in the storage area of the sound-light side RAM 355 can be eliminated. Thereafter, in the sound-light side RAM clearing process, the display control of the display control device 82 is performed so that the initial image and the model information image are displayed on the symbol display device 41, as in the 77th embodiment. As a result, the symbol display device 41 first starts displaying the initial image. As already described in the 77th embodiment, after the initial image is displayed for a predetermined time (for example, 3 seconds), the display content of the symbol display device 41 is switched from the initial image to the model information image.

After that, the date and time information of the RTC 356 is stored in the RTC memory 357 as reference time information of the demonstration effect (step SI802). As described above, the sound-light side CPU 353 waits for the start, and the difference between the reference time information of the demonstration effect stored in the RTC memory 357 and the current date and time information in the RTC 356 is a predetermined time (specifically, 15 seconds). ), the demonstration effect is started on the symbol display device 41. The reference time information of the demonstration effect stored in the RTC memory 357 in step SI802 is not cleared even if the sound light side RAM initialization process (step SI808) described later is executed. As a result, the reference time of the demonstration effect is deviated depending on the timing when the sound-light side CPU 353 receives any of the normal return command, the update return command, the confirmation return command, and the clear return command from the main CPU 63. Is prevented.

After that, in Step SI803 to Step SI807, the same processing as Step SI504 to Step SI508 of the sound-light side startup processing (FIG. 283) in the 77th embodiment is executed. Specifically, when the update start command is received from the main CPU 63 (step SI803: YES), the update notification setting process is executed (step SI804), and when the confirmation start command is received from the main CPU 63 (step SI804). In SI805: YES, the confirmation notification setting process is executed (step SI806). If it is determined in step SI807 that any of the normal return command, the update return command, the confirmation return command, and the clear return command have not been received from the main CPU 63, any return command is received. The processes of steps SI803 to SI807 are repeatedly executed until the command is received. The contents of the update notification setting process (step SI804) and the confirmation notification setting process (step SI806) are as already described in the 77th embodiment.

When it is determined in step SI807 that one of the return commands is received from the main CPU 63, the sound/light side RAM initialization processing is executed (step SI808). In the sound-light-side RAM initialization processing, when the update-time notification is being made when clearing “0” and initializing the sound-light-side RAM 355, the update-time notification is ended and the confirmation-time notification is made. If so, the confirmation notification is ended. On the other hand, even if the sound-light-side RAM initialization process is executed, the display of the model information image on the symbol display device 41 is not completed. The model information image continues to be displayed on the symbol display device 41 until the demonstration effect is started. In the sound/light side RAM initialization processing, as described above, all storage areas of the sound/light side RAM 355 are cleared to “0” and initialized. Even if the sound-light side RAM initialization process is executed, the reference time information of the demonstration effect stored in the RTC memory 357 in step SI802 is not cleared. As a result, the reference time of the demonstration effect is deviated depending on the timing when the sound-light side CPU 353 receives any of the normal return command, the update return command, the confirmation return command, and the clear return command from the main CPU 63. Is prevented.

After executing the sound-light side RAM initialization process in step SI808, "1" is set to the waiting state flag 555b provided in the sound-light side RAM 355 (step SI809). The waiting state flag 555b is a flag that allows the sound-light side CPU 353 to know that the start waiting state is in the same manner as in the 77th embodiment. When the wait state flag 555b is set to "1", the start wait state is entered.

After that, in Step SI810 to Step SI816, the same processing as Step SI511 to Step SI517 of the sound-light side startup processing (FIG. 283) in the 77th embodiment is executed. When the normal return notification setting process is executed in step SI811, the post-update notification setting process is executed in step SI813, the post-confirmation notification setting process is executed in step SI815, or in step SI816. When the clear return notification setting process is executed, the interruption of the sound light side timer interrupt processing (FIG. 284) is permitted (step SI817), and the sound light side start-up processing is ended.

Next, the start waiting effect process executed by the sound-light side CPU 353 will be described with reference to the flowchart of FIG. 289. The start waiting effect process is executed in step SI621 of the sound-light side timer interrupt process (FIG. 284), as in the 77th embodiment.

In Step SI901 to Step SI905, the same processing as Step SI701 to Step SI705 of the start waiting effect processing (FIG. 285) in the 77th embodiment is executed.

If it is determined in step SI902 that the waiting state flag 555b in the sound-light side RAM 355 is set to "1", or if the waiting state flag 555b is set to "1" in step SI905, that is, in the start waiting state. In some cases, the reference time of the demonstration effect is grasped based on the reference time information of the demonstration effect stored in the RTC memory 357 (step SI906), and the current date and time information in the RTC 356 is acquired (step SI907). After that, it is determined whether or not "1" is set in the start waiting effect flag provided in the sound-light side RAM 355. Similar to the 77th embodiment, the start wait effect flag enables the sound-light side CPU 353 to know that either the demonstration effect or the standby symbol display is being executed as the start wait effect. Is.

When "1" is not set in the start waiting effect flag (step SI908: NO), the demonstration effect is set based on the reference time of the demonstration effect acquired in step SI906 and the date and time information acquired in step SI907. It is determined whether it is the start timing (step SI909). Specifically, it is determined whether the elapsed time from the reference time of the demonstration effect is an integral multiple of 15 seconds, and if the elapsed time is an integral multiple of 15 seconds, it is the start timing of the demonstration effect. judge.

When it is determined in step SI909 that it is the start timing of the demonstration effect, the process proceeds to step SI910. In Step SI910 to Step SI911, the same processing as Step SI708 to Step SI709 of the start waiting effect processing (FIG. 285) in the 77th embodiment is executed. Specifically, "1" is set to the start waiting effect flag in the sound/light side RAM 355 (step SI910), the start setting process of the demonstration effect is executed (step SI911), and the process for the start waiting effect is ended. .. In the start setting process of the demonstration effect in step SI911, when the elapsed time from the reference time of the demonstration effect is an integral multiple of 15 seconds in the situation where the standby symbol display is performed (the positive determination in step SI914 described later If done) will also be executed. In the start setting process of the demonstration effect, when the model information image is being displayed on the symbol display device 41, the display control device 82 is controlled so that the display of the model information image is ended, and the symbol is also controlled. When the standby symbol display is being executed on the display device 41, the display control device 82 is controlled so that the standby symbol display ends. Then, the display control of the display control device 82 is performed so that the symbol display device 41 executes the demonstration effect. Note that the light emission control of the display light emitting unit 53 may be executed so that the display light emitting unit 53 emits light in the light emitting mode for the demonstration effect, and the speaker unit 54 outputs the sound so that the sound output for the demonstration effect is performed. It may be configured to control.

If an affirmative determination is made in step SI908, that is, if the start waiting effect (demo effect and standby symbol display) is already being executed, the reference time of the demonstration effect acquired in step SI906 and the acquisition in step SI907 It is determined whether or not it is the end timing of the demonstration effect based on the date and time information (step SI912). Specifically, when 10 seconds have elapsed since the demonstration effect was started in step SI911, it is determined to be the end timing of the demonstration effect. If it is the end timing of the demonstration effect (step SI911: YES), the start setting process of the standby symbol display is executed (step SI913), and the process for the start waiting effect is ended. In the standby symbol display start setting process in step SI913, the display control device 82 is controlled so that the demonstration effect executed in the symbol display device 41 ends and the standby symbol display in the symbol display device 41 starts. .. Note that the light emission control of the display light emitting unit 53 may be executed so that the display light emitting unit 53 emits light in the light emitting mode for displaying the standby symbol, and the speaker unit 54 is used so that the sound output for the standby symbol display is performed. It may be configured to control the sound output.

When a negative determination is made in step SI912, it is determined whether or not it is the start timing of the demonstration effect based on the reference time of the demonstration effect obtained in step SI906 and the date and time information acquired in step SI907. (Step SI914). Specifically, it is determined whether the elapsed time from the reference time of the demonstration effect is an integral multiple of 15 seconds, and if the elapsed time is an integral multiple of 15 seconds, it is the start timing of the demonstration effect. judge. When it is not the start timing of the demonstration effect (step SI914: NO), the main start waiting effect process is ended as it is. On the other hand, if it is the start timing of the demonstration effect (step SI914: YES), it means that 15 seconds have elapsed from the start timing of the previous demonstration effect and the start timing of the new demonstration effect has been reached. The demonstration effect start setting process in SI911 is executed, and the main start waiting effect process is ended. As a result, the standby symbol display is ended on the symbol display device 41 and a new demonstration effect is started.

According to this embodiment described in detail above, the following excellent effects are exhibited.

Date and time information is acquired from RT 356 in the sound-light side startup processing (FIG. 288) executed when the supply of operating power to the pachinko machine 10 is started, and the date and time information is used as reference time information for the demonstration effect. It is stored in the RTC memory 357. In the start waiting state, the start timing of the demonstration effect is grasped based on the reference time of the demonstration effect in the RTC memory 357 and the current date and time information in the RTC 356. In the sound-light side start-up process (FIG. 288), the external power is supplied from the start of the supply of the operating power to the pachinko machine 10 to the execution of the process of setting the reference time information of the demonstration effect in the RTC memory 357. Processing that requires an operation from is not performed. Further, a lottery or the like for changing the timing of acquiring the reference time information of the demonstration effect is not performed. Therefore, by starting the supply of the operating power to the plurality of pachinko machines 10 at the same time, the reference time of the demonstration effect in the plurality of pachinko machines 10 can be made the same or substantially the same time.

At the timing when the difference between the reference time information of the demonstration effect in the RTC memory 357 and the current date and time information in the RTC 356 is an integer multiple of a predetermined time (specifically 15 seconds) in the start waiting state, the symbol display device 41 The demonstration production starts. Therefore, in a plurality of pachinko machines 10 in which the reference times of the same or substantially the same demonstration effect are aligned with the same or substantially the same time, it is possible to create a situation in which the demonstration effects are simultaneously started in a waiting state. It will be possible. As a result, it is possible to give a sense of unity to the demonstration effect in the plurality of pachinko machines 10 and raise the player's interest in the pachinko machines 10.

As for the reference time information of the demonstration effect stored in the RTC memory 357, the sound-light side CPU 353 receives one of the return commands from the main-side CPU 63, and the sound-light side RAM initialization process (sound light side start-up process ( It is not cleared even if step SI808) of FIG. 288) is executed. Therefore, it is possible to prevent the reference time of the demonstration effect from being deviated due to the presence/absence of the “setting confirmation operation”, the “setting change operation”, and the “RAM clear operation” at the time of starting the supply of the operating power to the pachinko machine 10. ..

Since the reference time of the demonstration effect does not change depending on the presence/absence of “setting confirmation operation”, “setting change operation”, and “RAM clear operation”, supply of operating power to a plurality of pachinko machines 10 is started at the same time. In some cases, if a “setting confirmation operation”, a “setting change operation”, or a “RAM clear operation” is performed on some of the plurality of pachinko machines 10, the “setting confirmation operation” is performed. , "Setting change operation" and "RAM clear operation" were not performed, the reference time of the demonstration effect in the pachinko machine 10 and "setting confirmation operation", "setting change operation" or "RAM clear operation" was performed. The reference time of the demonstration effect in the pachinko machine 10 can be aligned as the same time. Thereby, it is possible to prevent the pachinko machine 10 for which the “setting confirmation operation”, the “setting change operation”, or the “RAM clear operation” has been performed based on the start timing of the demonstration effect from being easily identified. ..

The start timing table in which the start timing of the demonstration effect is set may be stored in advance in the sound-light side ROM 354, and the start timing of the demonstration effect may be grasped based on the start timing table. Specifically, in the start timing table, the timing at which the seconds portion of the date and time information in the RTC 356 is "00" seconds, "15" seconds, "33" seconds and "47" seconds is set as the start timing of the demonstration effect. Has been done. In this configuration, the start timing table is stored in the sound/light side ROM 354 before the interruption of the sound/light side timer interrupt processing (FIG. 284) is permitted in step SI817 of the sound/light side startup processing (FIG. 288). It is read to the RAM 355. In the start waiting effect process (FIG. 289), in the start waiting state, the seconds portion of the current date and time information acquired from the RTC 356 in step SI907 is compared with the start timing table, and the seconds portion is "00". If it is any one of seconds, “15” seconds, “33” seconds, or “47” seconds, it is determined that it is the start timing of the demonstration effect (step SI909: YES), and the demonstration effect is started. When the demonstration effect is started based on the fact that the seconds part of the current date and time information acquired from the RTC 356 is "00" seconds, the next demonstration effect will start 15 seconds later and the number of seconds of the current date and time information will be started. When the demonstration effect is started based on the part being "15" seconds, the next demonstration effect is started 18 seconds later, and the second part of the current date and time information is "33" seconds. When the demonstration effect is started, the next demonstration effect is started 14 seconds later, and when the demonstration effect is started based on the fact that the seconds portion of the current date and time information is “47” seconds, the next demonstration effect is started. The demonstration production of will start in 13 seconds. In this way, even in the configuration in which the demonstration effect is started when the seconds part of the current date and time information in the RTC 356 matches the number of seconds set in the start timing table in the start waiting state, the plurality of pachinko machines 10 can be used. The start timing of the demonstration production can be aligned. In this configuration, even when the supply of operating power to the plurality of pachinko machines 10 is started at different timings, the plurality of pachinko machines 10 are provided on the condition that the date and time information of the RTC 356 is complete. The start timing of the demonstration effect in the machine 10 can be aligned. This makes it possible to align the start timings of the demonstration effects in the plurality of pachinko machines 10 installed in the plurality of island facilities. Further, in the present configuration, the start timing of the demonstration effect in the plurality of pachinko machines 10 is set in a mode in which there are a plurality of time intervals as the time interval from the start timing of one demonstration effect to the start timing of the next demonstration effect. It becomes possible to arrange.

<79th Embodiment>
This embodiment is different from the 77th embodiment in that a timing change lottery for deciding whether to change the start timing of the demonstration effect is performed. The configuration different from that of the 77th embodiment will be described below. Note that the description of the same configuration as the 77th embodiment is basically omitted.

As already described in the 77th embodiment, the demonstration effect is started on the symbol display device 41 at the timing when the value of the timer counter 554a for starting the demo reaches the maximum value (specifically, “2999”) in the start waiting state. It In the present embodiment, when the sound-light side CPU 353 receives from the main-side CPU 63 any one of the normal return command, the confirmation return command, the update return command, and the clear return command, the sound-light side CPU 353 receives it. The timing change lottery described above is performed. The timing change lottery has a lottery result in which the start timing of the demonstration effect is not changed and a lottery result in which the start timing of the demonstration effect is changed. As a result, when the supply of the operating power to the plurality of pachinko machines 10 is started at the same time, the pachinko machine 10 which is the result of the lottery without changing the start timing of the demonstration effect in the timing change lottery and the start timing of the demonstration effect are selected. There is a high possibility that both the pachinko machine 10 that has changed the lottery result are present.

The random number information for lottery used for the timing change lottery is transmitted from the main CPU 63 to the sound/light side CPU 353. A configuration for the sound-light side CPU 353 to acquire random number information for lottery for timing change lottery will be described. FIG. 290(a) is an explanatory diagram for explaining the storage area provided in the work area 221 for specific control in the present embodiment. As shown in FIG. 290(a), random number information for lottery used in the timing change lottery executed by the sound-light side CPU 353 is set in the work area 221 for specific control of the main RAM 65 in the present embodiment. A transmission random number storage counter 556 is provided.

The transmission random number storage counter 556 has a storage capacity of 10 bits, and the transmission random number storage counter 556 is set with any numerical value information of “0” to “599”. In this embodiment, when the checksum is determined to be normal in step SB105 of the main process (FIG. 165), “0” to “stored in the random number initial value counter CINI in the work area 221 for specific control are stored. Any numerical value information of “599” is set in the transmission random number storage counter 556. On the other hand, when it is determined in step SB105 that the checksum is not normal, the transmission random number storage counter 556 is set with numerical information of “0”.

As already described in the first embodiment, the random number initial value counter CINI is incremented by 1 to the previous value each time it is updated, and reaches "0" after reaching the maximum value (specifically, "599"). It is a loop counter to return. The random number initial value updating process for updating the numerical information of the random number initial value counter CINI is already performed in step SI203 of the first timer interrupt process (FIG. 279) already described in the 77th embodiment, and already in the 49th embodiment. It is executed in step SB126 of the main process (FIG. 165) described above. The numerical value information of the random number initial value counter CINI is periodically updated in step SI203 of the first timer interrupt process (FIG. 279) and is also updated non-periodically in step SB126 of the main process (FIG. 165). ..

As already described in the forty-ninth embodiment, the residual process (steps SB125 to SB128) in the main process (FIG. 165) is the process of the first timer interrupt process (FIG. 279) and the second timer interrupt process (FIG. 281). It is performed using an irregular time that varies depending on the completion time. Therefore, the numerical information stored in the random number initial value counter CINI is not biased to a specific numerical range at the timing when the supply of operating power to the pachinko machine 10 is stopped. The processing completion time of the first timer interrupt processing (FIG. 279) varies depending on the manner of operation of the firing operation device 28 by the player, the manner of entering a game ball, and the like. Therefore, at the timing at which the supply of operating power to the pachinko machines 10 is stopped, the numerical information stored in the random number initial value counter CINI is different in the plurality of pachinko machines 10 except when it happens to coincide. Is becoming

In the present embodiment, even when the supply of operating power to the pachinko machine 10 is stopped, the work area 221 for specific control is set from the power supply unit for power interruption provided in the power supply/launch control device 78. Backup power is supplied to the main RAM 65, which includes the backup RAM, as power for holding the memory. As a result, the value of the random number initial value counter CINI in the work area 221 for specific control is stored and held even in the situation where the supply of operating power to the pachinko machine 10 is stopped.

As for the value of the random number initial value counter CINI, the supply of operating power to the pachinko machine 10 is stopped after the occurrence of a power failure is identified in the power failure information storage processing (step SI201 of the first timer interrupt processing (FIG. 279)). After that, the supply of the operating power is not restarted until the transmission random number storage counter 556 is set. Therefore, except when it is determined that the checksum is not normal in step SB105 of the main process (FIG. 165), the transmission random number storage counter 556 has a random number initial value counter when the supply of operating power to the pachinko machine 10 is stopped. The numerical information stored in CINI is set. As described above, if it is determined in step SB105 of the main process (FIG. 165) that the checksum is not normal, the transmission random number storage counter 556 is set to “0”.

As already described in the forty-ninth embodiment, in the main process (FIG. 165), when the supply of the operating power to the pachinko machine 10 is started, the reset button 68c is pressed without the ON operation of the setting key insertion part 68a. When the operation is performed (step SB108 or step SB120: YES, step SB114: NO), the first RAM clear process is executed on condition that the game stop flag is not set to "1" (step SB116: NO). (Step SB117). Further, as already described in the forty-ninth embodiment, in the main process (FIG. 165), the ON operation of the setting key insertion section 68a and the pressing operation of the reset button 68c are performed at the time of starting the supply of the operating power to the pachinko machine 10. If it has been performed (step SB108 or step SB120: YES, step SB114: YES), the set value update process (FIG. 167) is executed (step SB115). In the setting value updating process, the second RAM clearing process is executed in step SB313. In the first RAM clearing process and the second RAM clearing process, except for the area (that is, the setting reference area 341) in which the setting value information indicating the setting state of the pachinko machine 10 is set in the work area 221 for specific control, The work area 221 for the specific control is cleared to “0” and the initial setting is executed. Therefore, when the first RAM clearing process or the second RAM clearing process is executed, the value of the random number initial value counter CINI is cleared to "0". In the present embodiment, the timing at which the numerical information stored in the random number initial value counter CINI is set in the transmission random number storage counter 556 is the timing at which the checksum is determined to be normal in step SB105 of the main process (FIG. 165). This is a timing before the timing at which the first RAM clearing process (step SB117 of the main process (FIG. 165)) and the second RAM clearing process (step SB313 of the set value updating process (FIG. 167)) are executed. Further, the transmission random number storage counter 556 is not cleared to “0” in the first RAM clearing process and the second RAM clearing process. As a result, even when the reset button 68c is pressed at the start of supplying the operating power to the pachinko machine 10, the numerical information stored in the random number initial value counter CINI before being cleared to "0" is sounded. It is possible to transmit to the light side CPU 353.

When the main CPU 63 transmits any one of the normal return command, the update return command, the confirmation return command, and the clear return command to the sound/light side CPU 353, random number information for timing change lottery As a result, the numerical information stored in the transmission random number storage counter 556 in the specific control work area 221 is set in the return command to be transmitted.

As has already been described in the forty-ninth embodiment, the normal return command includes the setting confirmation process (step SB112), the set value update process (step SB115), and the first RAM clear process (step SB117) in the main process (FIG. 165). When the process at the start of supplying the operating power (steps SB101 to SB122) is completed without performing any of the above, the information is transmitted in step SB113. The clear return command is transmitted in step SB118 when the first RAM clear process is completed in step SB117 of the main process (FIG. 165) as described above. The return command upon confirmation is transmitted to the sound/light side CPU 353 in step SB207 of the setting confirmation process (FIG. 166). The return command at the time of updating is transmitted to the sound/light side CPU 353 in step SB314 of the setting value updating process (FIG. 167).

The transmission random number storage counter 556 clears “0” in the first RAM clearing process (step SB117 of the main process (FIG. 165)) and the second RAM clearing process (step SB313 of the setting value update process (FIG. 167)), and is an object of initial setting. Are excluded from the area. Therefore, the value of the transmission random number storage counter 556 is determined to be normal in step SB105 of the main process (FIG. 165), and the random number initial value counter CINI is set. Is not cleared before is sent. Therefore, when it is determined in step SB105 of the main process (FIG. 165) that the checksum is normal, one of the return commands transmitted from the main CPU 63 to the sound/light side CPU 353 includes a timing change lottery. As the random number information for lottery, the numerical value information stored in the random number initial value counter CINI of the work area 221 for specific control when the supply of the operating power to the pachinko machine 10 is stopped is set.

FIG. 290( b) is an explanatory diagram for explaining the non-initialization target area 554 and the initialization target area 555 in the sound-light side RAM 355. As shown in FIG. 290(b), a reception random number storage counter 554b is provided in the non-initialization area 554 of the sound-light side RAM 355. The received random number storage counter 554b is a counter for storing random number information for lottery for timing change lottery set in one of the return commands received from the main CPU 63 by the sound-light side CPU 353. The reception random number storage counter 554b is a 10-bit storage area, and the reception random number storage counter 554b stores random number information for lottery "0" to "599" received from the main CPU 63. As already described in the 77th embodiment, the non-initialization area 554 is cleared to “0” and initialized in the sound light side RAM initialization processing (step SJ110 of the sound light side startup processing (FIG. 291) described later). It is excluded from the setting target. Therefore, the sound-light side CPU 353 receives one of the return commands from the main-side CPU 63 and is executed in the sound-light side RAM initialization process (step SJ110 of the sound-light side startup process (FIG. 291) described later). The value of the random number storage counter 554b is not changed.

The random number information for changing timing, which is received by the sound-light side CPU 353 from the main CPU 63 and stored in the received random number storage counter 554b, is used as it is for the timing changing lottery. As a result, it is possible to carry out the timing changing lottery using the random number information for lottery, which has no bias in the numerical range. In addition, even when the supply of operating power to the plurality of pachinko machines 10 is started at the same time, the random number information for lottery used in the timing change lottery is different in the plurality of pachinko machines 10 except for the case of coincidence. It can be a value.

As in the 77th embodiment, the non-initialization area 554 and the initialization target area 555 of the sound-light side RAM 355 are not supplied with backup power when the supply of operating power to the pachinko machine 10 is stopped. It is an area. Immediately after the supply of operating power to the pachinko machine 10 is started, the storage areas of the non-initialization target area 554 and the initialization target area 555 are in an undefined state. Therefore, in order to eliminate the indefinite state in the storage areas of the non-initialization target area 554 and the initialization target area 555, step SJ101 of the sound light side RAM clear processing (sound light side startup processing (FIG. 291) described later). ) Must be performed.

As described above, the backup power is not supplied to the sound-light side RAM 355 in the state where the supply of the operating power to the pachinko machine 10 is stopped. Immediately after the supply of operating power to the pachinko machine 10 is started, the storage area of the sound/light side RAM 355 is in an indefinite state, and the sound/light side RAM clear processing (sound/light side startup processing (FIG. 291) described later) is performed. It is necessary to clear "0" in the non-initialization target area 554 and the initialization target area 555 in step SJ101). Therefore, a random number update counter for updating the random number information for timing change lottery is provided in the sound-light side RAM 355, and the random number update counter for receiving the random number for lottery for timing change lottery is not received from the main CPU 63. If the random number information for lottery is used for the timing change lottery, the random number update counter must be cleared to "0" in the sound-light-side RAM clearing process. In this configuration, the random number update counter is cleared to "0" in the sound/light side RAM clearing process (step SJ101 of the sound/light side startup process (FIG. 291) described later) and before the timing change lottery is performed. The number of times the random number information for lottery is updated may be the same or almost the same each time, and the result of the timing change lottery may always be the same. Further, when the supply of the operating power to the plurality of pachinko machines 10 is started at the same time, the timing change lottery results in the plurality of pachinko machines 10 may be the same. On the other hand, in the present embodiment, the random number information for timing change lottery is set in one of the return commands received by the sound-light side CPU 353 from the main side CPU 63, and the random number information for lottery is used. The timing change lottery is performed. As a result, random number information for lottery used in the timing change lottery is prevented from being biased to a specific numerical range, and the lottery result of the timing change lottery is generated with a probability different from the probability intended at the design stage. It is prevented from doing. Further, even when the supply of operating power to the plurality of pachinko machines 10 is started at the same time, the possibility that the timing change lottery results in the plurality of pachinko machines 10 are all the same is reduced.

The random number information for lottery received by the sound-light side CPU 353 from the main CPU 63 was updated in the random number initial value counter CINI in the work area 221 for specific control until the supply of operating power to the pachinko machine 10 is stopped. This is numerical information, and the transmission random number storage counter 556 is executed before the setting confirmation process (step SB112), the setting value update process (step SB115), and the first RAM clear process (step SB117) are performed in the main process (FIG. 165). It is the numerical information set to. The random number information for lottery used for the timing change lottery is not affected by the presence/absence of “setting confirmation operation”, “setting change operation”, and “RAM clear” at the time of starting the supply of operating power to the pachinko machine 10. This prevents the result of the timing change lottery from being unintentionally biased at the design stage depending on the presence/absence of the “setting confirmation operation”, the “setting change operation”, and the “RAM clear”, and at the start timing of the demonstration effect. Based on this, it is possible to prevent the pachinko machine 10 for which the “setting confirmation operation”, the “setting change operation”, or the “RAM clear operation” has been performed at the start of the supply of the operating power from being easily identified.

Next, the sound-light side startup processing executed by the sound-light side CPU 353 in this embodiment will be described with reference to the flowchart in FIG. The sound-light side startup process is executed when the supply of operating power to the pachinko machine 10 is started.

In steps SJ101 to SJ108, the same processes as steps SI501 to SI508 of the sound-light side startup process (FIG. 283) in the 77th embodiment are executed. When it is determined in step SJ108 that one of the return commands is received from the main CPU 63, the random number information for timing change lottery set in the received return command is set as the received random number in the non-initialization area 554. The data is stored in the storage counter 554b (step SJ109). As described above, the random number information for lottery for timing change lottery received from the main CPU 63 is stored in the random number initial value counter CINI in the work area 221 for specific control when the supply of the operating power to the pachinko machine 10 is stopped. The numerical information is "0" to "599", and the numerical information is not biased to a specific numerical range. Further, as already described, when the supply of operating power to the plurality of pachinko machines 10 is started at the same time, the lottery for the timing change lottery that the sound-light side CPU 353 receives from the main CPU 63 in the plurality of pachinko machines 10 The random number information has a different value except when coincidental.

After that, the sound-light side RAM initialization process is executed (step SJ110). As described above, the demonstration start timer counter 554a and the received random number storage counter 554b are provided in the non-initialization target area 554, and the non-initialization target area 554 clears “0” of the sound-light side RAM initialization process. And excluded from the subject of initialization. Therefore, even if the sound-light side RAM initialization process is executed in step SJ110, the values of the demo start timer counter 554a and the received random number storage counter 554b are not changed. Then, the timing change lottery process is executed (step SJ111). FIG. 292(a) is a flowchart showing the timing change lottery process.

In the timing change lottery process, the timing change lottery table used for the timing change lottery is read from the sound-light side ROM 354 to the initialization target area 555 of the sound-light side RAM 355 (step SJ201). FIG. 292(b) is an explanatory diagram for explaining the timing change lottery table 557. As shown in FIG. 292(b), in the timing change lottery table 557, a lottery result in which the start timing of the demonstration effect is not changed and a lottery result in which the start timing of the demonstration effect is changed are set.

In the timing change lottery, when the random number for lottery in the received random number storage counter 554b is in the numerical range of "0" to "539", the start timing of the demonstration effect is not changed, and the lottery random number is "540". In the case of the numerical value range of "~599", the result of the lottery is that the start timing of the demonstration effect is changed. In the timing change lottery, the probability of a lottery result in which the start timing of the demonstration effect is not changed is set to 9/10, and the probability of a lottery result in which the start timing of the demonstration effect is changed is set to 1/10. ing.

For this reason, when a plurality of pachinko machines 10 are installed on one island facility, the demo production start timing is the number of the pachinko machines 10 that are the result of the lottery in which the start timing of the demonstration effect is not changed in the timing change lottery. There is a high possibility that the number of pachinko machines 10 will be larger than the number of pachinko machines 10 that will result in a change in the lottery. Furthermore, it is a part of the plurality of pachinko machines 10 installed in one island facility, and the start timing of the demonstration production on the majority side of the pachinko machines 10 is unchanged, and the remaining minority side machines. It is highly possible that the start timing of the demonstration effect in the pachinko machine 10 is changed and the situation is shifted from the start timing of the demonstration effect in the pachinko machine 10 on the multiple side.

By aligning the start timings of the demonstration effects in the pachinko machines 10 on the large number of sides, it is possible to give the demonstration effects a sense of unity and improve the interest of the game. Then, with respect to the minority-side pachinko machine 10 whose start timing of the demonstration effect is different from that of the majority-side pachinko machine 10, the player feels a special feeling, and the player's interest in the minority-side pachinko machine 10 is increased. be able to. For example, regarding the minority side pachinko machine 10 whose start timing of the demonstration effect is different from the majority side pachinko machine 10, at the time of starting the supply of the operating power to the pachinko machine 10, only "setting" is performed for the minority side pachinko machine 10. It can be inferred that a "confirmation operation", a "setting change operation", or a "RAM clear operation" has been performed.

Returning to the explanation of the timing change lottery process (FIG. 292(a)), after reading the timing change lottery table 557 in step SJ201, the lottery stored in the received random number storage counter 554b of the non-initialization area 554 is used. Grasp the numerical information of the random number (step SJ202). After that, by comparing the numerical information of the random number for lottery grasped at step SJ202 with the timing change lottery table 557 read at step SJ201, it is specified whether or not the start timing of the demonstration effect is changed.

When the result of the lottery does not change the start timing of the demonstration effect (step SJ203: NO), the process for adding the timing change lottery (step SJ204) is not performed and the timing change lottery process is directly executed. finish. On the other hand, when the result of the lottery for changing the start timing of the demonstration effect is obtained (step SJ203: YES), the addition process of the demo start timer counter 554a is executed (step SJ204), and the process for this timing change lottery is executed. finish.

In the addition process of the demo start timer counter 554a in step SJ204, "1400" is added to the value of the demo start timer counter 554a. As described above, the demonstration start timer counter 554a is a loop counter that is updated in the numerical range of "0" to "2999". When the demo start timer counter 554a is added while the value of the demo start timer counter 554a is "1600" or more, the value of the demo start timer counter 554a after the addition of "1400" is the maximum value. Therefore, the value of the demo start timer counter 554a is a value obtained by subtracting "3000" from the value after the addition of "1400".

In this way, when the lottery result of changing the start timing of the demonstration effect is changed in the timing change lottery, the start timing of the demonstration effect is compared with the case of the lottery result of not changing the start timing of the demonstration effect. 7 seconds ahead of schedule. When supply of operating power to a plurality of pachinko machines 10 is started at the same time, the lottery that does not change the start timing of the demonstration effect is performed in the pachinko machine 10 that has the result of changing the start timing of the demonstration effect in the timing change lottery. Compared with the pachinko machine 10 that resulted, the value of the timer counter 554a for starting the demo reaches the maximum value (specifically “2999”) 7 seconds earlier, and the demonstration effect is 7 in the start waiting state. It will be started a few seconds earlier.

Returning to the description of the sound-light side startup processing (FIG. 291), after executing the timing change lottery processing in step SJ111, "1" is set to the waiting status flag 555b in the initialization target area 555 to start the waiting status. (Step SJ112). Similar to the 77th embodiment, in the start waiting state, the demonstration effect is displayed on the symbol display device 41 based on that the value of the timer counter 554a for starting the demo has reached the maximum value (specifically, 2999). Be started.

Thereafter, in steps SJ113 to SJ119, the same processing as steps SI511 to SI517 of the sound-light side startup processing (FIG. 283) of the 77th embodiment is executed, and the sound-light side startup processing is ended. ..

According to this embodiment described in detail above, the following excellent effects are exhibited.

After the value of the demo start timer counter 554a is cleared to "0" in the sound light side RAM clear processing (step SJ101 of the sound light side start-up processing (FIG. 291)), the timing change lottery is performed. In the case where the result of changing the start timing of the demonstration effect is obtained in the timing change lottery, a predetermined numerical value (specifically, "1400") is added to the demo start timer counter 554a, and the demo start timer counter is added. The timing at which the value of 554a reaches the maximum value (specifically, "2999") is shifted. When the supply of operating power to a plurality of pachinko machines 10 is started at the same time, the start timing of the demonstration effect in some of the pachinko machines 10 that results in a lottery that changes the start timing of the demonstration effect in the timing change lottery. It is possible to increase the possibility of a situation in which the start timing of the demonstration effect in the remaining pachinko machines 10 that have resulted in the lottery without changing the start timing of the demonstration effect is shifted. By creating a situation in which there are two start timings for the demonstration effect, it is possible that a set value that is advantageous to the player is set only for the pachinko machine 10 that has either one of the start timings for the demonstration effect. The player's interest in the pachinko machine 10 can be increased by inferring whether or not there is any.

In the timing change lottery, the probability of a lottery result in which the start timing of the demonstration effect is not changed is set to 90%, and the probability of a lottery result in which the start timing of the demonstration effect is changed is set to 10%. .. As a result, when the supply of operating power to the plurality of pachinko machines 10 is started at the same time, the start timings of the demonstration effects in the plurality of pachinko machines 10 that are part of the plurality of pachinko machines 10 are aligned. At the same time, there is an increased possibility that the start timing of the demonstration effect on the remaining minority-side pachinko machine 10 will deviate from the start timing of the demonstration effect on the majority-side pachinko machine 10. By aligning the start timings of the demonstration effects in the pachinko machines 10 on the multiple sides, it is possible to give a sense of unity to the demonstration effects and increase the player's interest in the pachinko machines 10. Further, the player is given a special feeling about the minority-side pachinko machine 10 whose start timing of the demonstration effect is different from the majority-side pachinko machine 10, and the player's interest in the minority-side pachinko machine 10 is increased. It can be further enhanced. For example, regarding the minority side pachinko machine 10 whose start timing of the demonstration effect is different from the majority side pachinko machine 10, at the time of starting the supply of the operating power to the pachinko machine 10, only "setting" is performed for the minority side pachinko machine 10. It is possible to increase the player's interest in the pachinko machine 10 on the minority side by inferring that the “confirmation operation” or the “setting change operation” may have been performed.

In the sound-light side RAM clearing process (step SJ101 of the sound-light side start-up process (FIG. 291)) executed based on the start of the supply of operating power to the pachinko machine 10, the value of the timer counter 554a for starting the demo Is cleared to "0". On the other hand, in the sound-light-side RAM initialization processing (step SJ110 of the sound-light-side startup processing (FIG. 291)) performed based on the sound-light-side CPU 353 receiving one of the return commands from the main-side CPU 63, the demonstration is started. The value of the timer counter 554a for use is not cleared to "0". Further, the demonstration effect is started at the timing when the value of the timer counter 554a for starting the demonstration reaches the maximum value in the start waiting state. Therefore, it is possible to prevent the timing at which the value of the demo start timer counter 554a reaches the maximum value from changing depending on the presence/absence of the “setting confirmation operation” and the “setting change operation”, and to perform the “setting confirmation operation”. Also, the start timing of the demonstration effect is prevented from changing depending on the presence or absence of the "setting change operation". This prevents the pachinko machine 10 on which the “setting confirmation operation” and the “setting change operation” have been performed based on the start timing of the demonstration effect from being easily identified.

In the configuration in which it is prevented that the presence or absence of the “setting confirmation operation” and the “setting change operation” are easily identified based on the start timing of the demonstration effect, the start timing of the demonstration effect is set as the lottery result of the timing change lottery. There are lottery results that do not change and lottery results that change the start timing of the demonstration effect. For this reason, the pachinko machine 10 on the minority side of the plurality of pachinko machines 10 is configured with a configuration in which it is practically impossible to identify the pachinko machine 10 for which the setting value that is advantageous for the player is set based on the start timing of the demonstration effect. It is possible to give a sense of expectation that the machine 10 is set with a setting value that is advantageous to the player. As a result, the player's interest in the pachinko machine 10 can be increased.

The random number information for lottery received by the sound-light side CPU 353 from the main CPU 63 was updated in the random number initial value counter CINI in the work area 221 for specific control until the supply of operating power to the pachinko machine 10 is stopped. This is numerical information, and the transmission random number storage counter 556 is executed before the setting confirmation process (step SB112), the setting value update process (step SB115), and the first RAM clear process (step SB117) are performed in the main process (FIG. 165). It is the numerical information set to. The random number information for lottery used for the timing change lottery is not affected by the presence/absence of “setting confirmation operation”, “setting change operation”, and “RAM clear” at the time of starting the supply of operating power to the pachinko machine 10. This prevents the result of the timing change lottery from being unintentionally biased at the design stage depending on the presence/absence of the “setting confirmation operation”, the “setting change operation”, and the “RAM clear”, and at the start timing of the demonstration effect. Based on this, it is possible to prevent the pachinko machine 10 for which the “setting confirmation operation”, the “setting change operation”, or the “RAM clear operation” has been performed at the start of the supply of the operating power from being easily identified.

The main CPU 63 uses the numerical information stored in the random number initial value counter CINI in the work area 221 for specific control when the supply of the operating power to the pachinko machine 10 is stopped, as the random number information for the timing change lottery, as the random number information for the sound change. It is transmitted to the side CPU 353. Since the sound/light side CPU 353 is configured to receive the random number information for the timing change lottery from the main side CPU 63, the structure for supplying the backup power to the sound/light side RAM 355 is unnecessary, and the pachinko machine 10 is operated. After the supply of the operating power is started, the timing change lottery can be performed early using the random number information for lottery with no deviation in the numerical range. As a result, it is possible to execute the timing change lottery early after the supply of the operating power to the pachinko machine 10 is started, and a plurality of game machines installed in one island facility at the start of the business hours of the game hall. The start timings of the demo effects in the pachinko machines 10 on the majority side, which are a part of the other pachinko machines 10, are not changed, and the start times of the demo effects on the remaining pachinko machines 10 are changed. As a result, there is a high possibility that the situation may deviate from the start timing of the demonstration effect in the pachinko machine 10 on the large number side.

It should be noted that the audio emission control board 351 is provided with a storage memory to which backup power for storing and holding information is supplied in a state in which the supply of operating power to the pachinko machine 10 is stopped. The random number information for change lottery may be updated. Specifically, the storage memory provided on the sound emission control board 351 is provided with a random number for lottery, which updates random number information for timing change lottery. The random number counter for lottery is a loop counter that is incremented by 1 in the numerical range of “0” to “599” and returns to “0” after reaching the maximum value. The sound-light side CPU 353 updates the lottery random number counter on condition that it is in the start waiting state in the sound-light side timer interrupt processing (FIG. 284). The period in the start waiting state is a period that varies depending on the manner of operation of the firing operation device 28 by the player, the manner of entering a game ball, and the like. Therefore, it is possible to prevent the random number information for lottery stored in the random number for lottery from being biased to a specific numerical range when the supply of operating power to the pachinko machine 10 is stopped. Further, the random number information for lottery stored in the random number counters for lottery in the plurality of pachinko machines 10 can be set to different values, except in the case of coincidence. As described above, the backup power is supplied to the storage memory even when the supply of the operating power to the pachinko machine 10 is stopped, and the lottery random number information stored in the lottery random number counter is stored and retained. Therefore, after the supply of the operating power to the pachinko machine 10 is started, it is possible to obtain the random number information for lottery with no deviation in the numerical range early. In addition, it is possible to reduce the possibility that random number information for lottery acquired by the plurality of pachinko machines 10 will be the same when the supply of operating power to the plurality of pachinko machines 10 is started at the same time.

Further, the sound/light side RAM 355 is provided with a lottery random number counter for updating the random number information for the timing change lottery, and in the state where the supply of operating power to the pachinko machine 10 is stopped, the sound/light side is provided. A configuration may be adopted in which backup power for storing and holding information in the RAM 355 is supplied. Specifically, the random number counter for lottery is a loop counter that is incremented by 1 in the numerical range of “0” to “599” and returns to “0” after reaching the maximum value. The sound-light side CPU 353 updates the lottery random number counter on condition that it is in the start waiting state in the sound-light side timer interrupt processing (FIG. 284). The period in the start waiting state is a period that varies depending on the manner of operation of the firing operation device 28 by the player, the manner of entering a game ball, and the like. Therefore, it is possible to prevent the random number information for lottery stored in the random number for lottery from being biased to a specific numerical range when the supply of operating power to the pachinko machine 10 is stopped. Further, the random number information for lottery stored in the random number counters for lottery in the plurality of pachinko machines 10 can be set to different values, except in the case of coincidence. In this configuration, the random number counter for lottery in the sound-light side RAM 355 has a sound-light side RAM clearing process (step SJ101 of sound-light side startup process (FIG. 291)) and a sound-light side RAM initialization process (sound light side startup process). In step SJ110) of the process (FIG. 291), it is excluded from the target of clearing “0”. Since the backup power is supplied to the sound/light side RAM 355 even when the supply of the operation power to the pachinko machine 10 is stopped, the sound/light side RAM 355 of the sound/light side RAM 355 is immediately stored after the supply of the operation power to the pachinko machine 10 is started. The storage area is prevented from entering an indefinite state. Thus, the random number counter for lottery is stopped when the supply of the operating power to the pachinko machine 10 is stopped last time without clearing the value of the random number counter for lottery to "0" in the sound-light-side RAM clearing process and the sound-light-side RAM initialization process. The update of the random number counter for lottery can be restarted from the value stored in. Therefore, after the supply of the operating power to the pachinko machine 10 is started, it is possible to obtain the random number information for lottery with no deviation in the numerical range early. In addition, it is possible to reduce the possibility that random number information for lottery acquired by the plurality of pachinko machines 10 will be the same when the supply of operating power to the plurality of pachinko machines 10 is started at the same time.

Further, an EEPROM that does not require external power supply for storing and holding information may be provided in the voice emission control board 351, and the random number information for the timing change lottery may be updated in the EEPROM. Specifically, the EEPROM is provided with a lottery random number counter for updating lottery random number information for timing change lottery. The random number counter for lottery is a loop counter that is incremented by 1 in the numerical range of “0” to “599” and returns to “0” after reaching the maximum value. The sound-light side CPU 353 updates the lottery random number counter on condition that it is in the start waiting state in the sound-light side timer interrupt processing (FIG. 284). The period in the start waiting state is a period that varies depending on the manner of operation of the firing operation device 28 by the player, the manner of entering a game ball, and the like. Therefore, it is possible to prevent the random number information for lottery stored in the random number for lottery from being biased to a specific numerical range when the supply of operating power to the pachinko machine 10 is stopped. Further, the random number information for lottery stored in the random number counters for lottery in the plurality of pachinko machines 10 can be set to different values, except in the case of coincidence. The random number information for lottery stored in the EEPROM is stored and held even when the supply of operating power to the pachinko machine 10 is stopped. For this reason, it is possible to obtain random number information for lottery with no deviation in the numerical range early after the supply of the operating power to the pachinko machine 10 is started, without requiring the configuration for supplying the backup power. In addition, it is possible to reduce the possibility that random number information for lottery acquired by the plurality of pachinko machines 10 will be the same when the supply of operating power to the plurality of pachinko machines 10 is started at the same time.

Further, in the case of a lottery result of changing the start timing of the demonstration effect in the timing change lottery, instead of the addition process (timing change lottery process (step SJ204 of FIG. 292(b)) of the demo start timer counter 554a. The demo start timer counter 554a may be configured to change the maximum value.Specifically, in the non-initialization target area 554 of the sound-light side RAM 355, the maximum value of the demo start timer counter 554a is set. A maximum value counter that is set is provided in the maximum value counter when the initial setting is performed in the sound light side RAM clear processing (step SJ101 of the sound light side startup processing (FIG. 291)). The maximum value (for example, “2999”) is set.Since the maximum value counter is provided in the non-initialization area 554, the value of the maximum value counter is the sound light side RAM initialization processing (sound light side startup processing (Step SJ110 in FIG. 291) No change is made in the timing change lottery, if the lottery result does not change the start timing of the demonstration effect, the value of the maximum value counter is not changed. Value reaches the first maximum value (specifically, "2999") at intervals of 15 seconds.On the other hand, in the timing change lottery, the maximum value counter is displayed when the result of the demonstration production start timing is changed. A second maximum value (for example, “3399”) is set.In this case, the value of the demo start timer counter 554a reaches the maximum value (specifically “3399”) at intervals of 17 seconds. Even if the maximum value of the timer counter 554a for starting the demo is changed according to the result of the change lottery, the start timing of the demonstration effect can be different according to the result of the timing change lottery.

<80th Embodiment>
In this embodiment, the content of the timing change lottery process is different from that of the 79th embodiment. The configuration different from that of the 79th embodiment will be described below. Note that the description of the same configuration as the 79th embodiment is basically omitted.

FIG. 293(a) is a flowchart showing the timing changing lottery process executed by the sound/light side CPU 353 in the present embodiment. The timing change lottery process is executed in step SJ111 of the sound-light side startup process (FIG. 291), as in the 79th embodiment.

In the timing change lottery process, the timing change lottery table used for the timing change lottery is read from the sound-light side ROM 354 to the initialization target area 555 of the sound-light side RAM 355 (step SJ301). FIG. 293(b) is an explanatory diagram for explaining the timing change lottery table 558. As shown in FIG. 293(b), in the timing change lottery table 558, "0", "800", "1600" and "2400" are set as the values set in the demo start timer counter 554a after the timing change lottery. Numerical information is set.

In the timing change lottery, when the random number information for lottery stored in the received random number storage counter 554b is in the numerical range of “0” to “149”, “0” is set to the demonstration start timer counter 554a, When the random number information for lottery is in the numerical range of “150” to “299”, “800” is set in the timer counter 554a for starting the demo, and the random number information for random selection is in the numerical range of “300” to “449”. "1600" is set in the demonstration start timer counter 554a, and when the random number information for lottery is in the numerical range of "450" to "599", "2400" is set in the demo start timer counter 554a. Is set. In the timing change lottery, the probability that the demo start timer counter 554a is set to "0" after the timing change lottery, the probability that the demo start timer counter 554a is set to "800", and the demo start timer counter 554a is set to " The probability that "1600" is set and the probability that "2400" is set in the timer counter 554a for starting a demonstration are "1/4", which are the same. As a result, after the supply of the operating power to the plurality of pachinko machines 10 is started at the same time, the values of the demo start timer counters 554a in the plurality of pachinko machines 10 can be evenly distributed by the timing change lottery. Is becoming

Returning to the explanation of the timing change lottery process (FIG. 293(a)), after reading the timing change lottery table 557 in step SJ301, the lottery stored in the received random number storage counter 554b of the non-initialization area 554 is used. Grasp the random number information (step SJ302). As already described in the 79th embodiment, the random number information for lottery stored in the received random number storage counter 554b is the work area 221 for specific control until the supply of operating power to the pachinko machine 10 is stopped. It is the numerical value information that has been updated in the random number initial value counter CINI in. This prevents the value of the random number information for lottery used for the timing change lottery from being biased to a specific numerical range. Also, the numerical information for random numbers is transmitted before the setting confirmation process (step SB112), the set value update process (step SB115), and the first RAM clear process (step SB117) are performed in the main process (FIG. 165). This is numerical information set in the random number storage counter 556. Therefore, the random number information for lottery used for the timing change lottery is not affected by the presence/absence of the “setting confirmation operation”, the “setting change operation”, and the “RAM clear” at the time of starting the supply of the operating power to the pachinko machine 10. .. This prevents the result of the timing change lottery from being unintentionally biased at the design stage depending on the presence/absence of the “setting confirmation operation”, the “setting change operation”, and the “RAM clear”, and at the start timing of the demonstration effect. Based on this, it is possible to prevent the pachinko machine 10 for which the “setting confirmation operation”, the “setting change operation”, or the “RAM clear operation” has been performed at the start of the supply of the operating power from being easily identified.

Then, the random number information for lottery grasped at step SJ302 is collated with the timing change lottery table 558 read at step SJ301 to identify the numerical information to be set in the demonstration start timer counter 554a (step SJ303). The numerical information thus set is set in the timer counter 554a for starting the demonstration (step SJ304), and the processing for the timing change lottery is ended. As a result, the timing at which the value of the demo start timer counter 554a in the non-initialization area 554 reaches the maximum value (specifically, “2999”) in a manner corresponding to the lottery result of the timing change lottery, The timing at which the value of the demo start timer counter 554a reaches the maximum value and the demonstration effect is started in the start waiting state is changed.

According to this embodiment described in detail above, the following excellent effects are exhibited.

In the timing change lottery, four kinds of numerical value information (“0”, “800”, “1600” set in the demo start timer counter 554a are arranged in a manner corresponding to the random number for lottery stored in the received random number storage counter 554b. ,” and “2400”) are selected. The probability that the four types of numerical information are selected as the numerical information set in the demo start timer counter 554a in the timing change lottery is "1/4" and is the same. Therefore, when the supply of operating power to the plurality of pachinko machines 10 is started at the same time, it is possible to evenly distribute the timing at which the demonstration effect is started in the plurality of pachinko machines 10.

The random number information for lottery used for the timing change lottery is the numerical information updated in the random number initial value counter CINI in the work area 221 for specific control until the supply of operating power to the pachinko machine 10 is stopped. This prevents the value of the random number information for lottery used for the timing change lottery from being biased to a specific numerical range. Also, the numerical information for random numbers is transmitted before the setting confirmation process (step SB112), the set value update process (step SB115), and the first RAM clear process (step SB117) are performed in the main process (FIG. 165). This is numerical information set in the random number storage counter 556. Therefore, the random number information for lottery used for the timing change lottery is not affected by the presence/absence of the “setting confirmation operation”, the “setting change operation”, and the “RAM clear” at the time of starting the supply of the operating power to the pachinko machine 10. .. This prevents the result of the timing change lottery from being unintentionally biased at the design stage depending on the presence/absence of the “setting confirmation operation”, the “setting change operation”, and the “RAM clear”, and at the start timing of the demonstration effect. Based on this, it is possible to prevent the pachinko machine 10 for which the “setting confirmation operation”, the “setting change operation”, or the “RAM clear operation” has been performed at the start of the supply of the operating power from being easily identified.

Note that instead of the configuration for determining the numerical information to be set in the demo start timer counter 554a by the timing change lottery, the maximum value of the demo start timer counter 554a may be determined by the timing change lottery. Specifically, the non-initialization area 554 of the sound-light side RAM 355 is provided with a maximum value counter for setting the maximum value of the demo start timer counter 554a. The maximum value counter is set to the first maximum value (for example, “2999”) when the initialization is performed in the sound light side RAM clear processing (step SJ101 of the sound light side start-up processing (FIG. 291)). .. Since the maximum value counter is provided in the non-initialization area 554, the value of the maximum value counter is not changed in the sound light side RAM initialization process (step SJ110 of the sound light side start-up process (FIG. 291)). In the timing change lottery, the first maximum value (specifically “2999”) is selected as the maximum value of the timer counter 554a for starting the demonstration, and the second maximum value (specifically “3199”) is selected as the selection result. The selected lottery result, the third maximum value (specifically, “3399”) is selected, and the fourth maximum value (specifically, “3599”) is selected. It occurs with a probability of 4". The value of the demo start timer counter 554a reaches the first maximum value at 15-second intervals when the first maximum value is set as the maximum value of the demo start timer counter 554a, and the second maximum value is set. If it is set, the second maximum value is reached at 16-second intervals, if the third maximum value is set, the third maximum value is reached at 17-second intervals, and if the fourth maximum value is set. The fourth maximum value is reached at 18-second intervals. In this way, even if the maximum value of the timer counter 554a for starting the demonstration is changed according to the result of the timing change lottery, the start timing of the demonstration effect can be different according to the result of the timing change lottery.

Further, the configuration for changing the start timing of the demonstration effect is not limited to the configuration in which the numerical information corresponding to the lottery result of the timing change lottery is set in the demo start timer counter 554a. For example, the numerical information may be set in the demonstration start timer counter 554a without performing the lottery. Specifically, the sound-light side CPU 353 receives the return command (normal return command, update return command, check return command, and clear return command received from the main CPU 63 as in the 80th embodiment. Numerical value information of any of “0” to “599” set in any of the commands) is stored in the received random number storage counter 554b. As already described in the 80th embodiment, the numerical information set in the return command is the random number initial value counter in the work area 221 for specific control until the supply of operating power to the pachinko machine 10 is stopped. It is the numerical information that has been updated in CINI, and is the numerical information that is prevented from being biased to a specific numerical range. The sound-light side CPU 353 executes the sound-light side RAM initialization process in step SJ110 of the sound-light side startup process (FIG. 291), and then executes the timing change lottery process (step SJ111) in the 80th embodiment. The numerical value information of any one of "0" to "599" stored in the received random number storage counter 554b is set in the demonstration start timer counter 554a without being executed. As a result, the timing at which the demo start timer counter 554a first reaches the maximum value (specifically, 2999) varies depending on the numerical information set in the demo start timer counter 554a after the sound-light-side RAM initialization processing. Can be made. When supply of operating power to a plurality of pachinko machines 10 is started at the same time, the plurality of amusement machines according to the numerical information set in the demo start timer counter 554a after the sound-light side RAM initialization process. In, the timing at which the value of the demo start timer counter 554a reaches the maximum value can be set to different timings, and the start timing of the demonstration effect can be set to different timings. Numerical information set in the demo start timer counter 554a after the sound-light-side RAM initialization process is the setting confirmation process (step SB112), the set value update process (step SB115), and the first RAM clear in the main process (FIG. 165). This is the numerical information set in the transmission random number storage counter 556 before the processing (step SB117) is performed. Therefore, the numerical information is not affected by the presence/absence of the “setting confirmation operation”, the “setting change operation”, and the “RAM clear” when the supply of the operating power to the pachinko machine 10 is started. As a result, depending on the presence/absence of the “setting confirmation operation”, the “setting change operation”, and the “RAM clear”, the numerical information set in the demo start timer counter 554a after the sound-light side RAM initialization processing is unintentionally biased at the design stage Are prevented from occurring. Further, it is possible to prevent the pachinko machine 10 for which the “setting confirmation operation”, the “setting change operation” or the “RAM clear operation” has been performed at the start of the supply of the operating power based on the start timing of the demonstration effect from being easily identified. Has been done.

<81st Embodiment>
This embodiment differs from the 77th embodiment in that a plurality of types of demonstration effects and standby symbol display are executed. The configuration different from that of the 77th embodiment will be described below. Note that the description of the same configuration as the 77th embodiment is basically omitted.

In the present embodiment, there are three types of first demonstration effect, second demonstration effect, and third demonstration effect as the demonstration effects executed by the symbol display device 41, and they are executed by the symbol display device 41. As the standby symbol display, there are three types of first standby symbol display, second standby symbol display and third standby symbol display. The execution period of each of the first to third demonstration effects is 10 seconds.

FIG. 294 is an explanatory diagram for explaining the configuration of the sound-light side RAM 355 in this embodiment. As shown in FIG. 294, in the present embodiment, a non-initialization target area 554 of the sound-light side RAM 355 is provided with a demonstration effect type counter 554c in addition to the demonstration start timer counter 554a. The demonstration effect type counter 554c is a counter that allows the sound-light side CPU 353 to grasp the type of demonstration effect to be executed and the type of standby symbol display. Numerical information of any of “0” to “2” is set in the demonstration effect type counter 554c. If the value of the demonstration effect type counter 554c is "0", the first demonstration effect and the first standby symbol display are the execution targets, and if the value of the demonstration effect type counter 554c is "1", The 2 demonstration effects and the second standby symbol display are the execution targets, and when the value of the demonstration effect type counter 554c is "3", the third demonstration effects and the third standby symbol display are the execution targets.

In the update process of the demo start timer counter 554a (step SI601 of the sound-light timer interrupt process (FIG. 284)) in the present embodiment, the value of the demo start timer counter 554a is the maximum value (specifically, “2999”). When the update process (step SI601) is executed in such a state to clear the value of the demonstration start timer counter 554a to "0", the update process of the demonstration effect type counter 554c is executed. In the updating process of the demo effect type counter 554c, the value of the demo effect type counter 554c is incremented by 1, and when the value of the demo effect type counter 554c after adding 1 is "3", the demo is performed. The value of the production type counter 554c is cleared to "0". As a result, the types of the demonstration effect and the standby symbol display to be executed in the symbol display device 41 are updated.

In the present embodiment, in the demo effect start setting process (step SI709 of the start waiting effect process (FIG. 285)), the setting for executing the demo effect corresponding to the value of the demo effect type counter 554c is performed. Specifically, when the value of the demo effect type counter 554c is "0", the setting for starting the first demo effect is performed, and when the value of the demo effect type counter 554c is "1". The setting for starting the second demonstration effect is performed, and the setting for starting the third demonstration effect is performed when the value of the demonstration effect type counter 554c is "3". Also, in the standby symbol display start setting process (step SI711 of the start waiting effect process (FIG. 285)), the setting for executing the standby symbol display corresponding to the value of the demonstration effect type counter 554c is performed. Specifically, when the value of the demo effect type counter 554c is "0", the setting for starting the first standby symbol display is performed, and the value of the demo effect type counter 554c is "1". The setting for starting the second standby symbol display is performed, and the setting for starting the third standby symbol display is performed when the value of the demonstration effect type counter 554c is "3".

In the update process of the demo start timer counter 554a (step SI601 of the sound-light side timer interrupt process (FIG. 284)), the value of the demo effect type counter 554c is updated in a manner linked with the update of the demo start timer counter 554a. To be done. Therefore, by simultaneously supplying the operating power to the plurality of pachinko machines 10 and arranging the timings at which the value of the demo start timer counter 554a reaches the maximum value (specifically, “2999”), The values of the demonstration effect type counter 554c in the pachinko machine 10 can also be aligned. Thereby, while the demonstration effect and the standby symbol display that can be executed in the symbol display device 41 are set to a plurality of types, the types of the demonstration effect and the standby symbol display that are simultaneously started in the plurality of pachinko machines 10 can be aligned.

Since the demo start timer counter 554a and the demo effect type counter 554c are provided in the non-initialization area 554, the demo start timer counter 554a and the demo effect type counter 554c perform the sound-light-side RAM clearing process (sound). While "0" is cleared in the light side startup process (step SI501) (FIG. 283), "0" is not cleared in the sound beam side RAM initialization process (step SI509 in the sound beam side startup process (FIG. 283)). .. Therefore, the values of the demo start timer counter 554a and the demo effect type counter 554c depend on the presence/absence of the “setting confirmation operation”, the “setting change operation”, and the “RAM clear processing” at the time of starting the supply of the operating power to the pachinko machine 10. Is not changed.

When the supply of operating power to a plurality of pachinko machines 10 is started at the same time, the start timing of the demonstration effect is prevented from being shifted due to the presence/absence of "setting confirmation operation", "setting change operation" and "RAM clear processing" In addition, the types of the demonstration effect and the standby symbol display are prevented from shifting. This prevents the pachinko machine 10 for which the “setting confirmation operation”, the “setting change operation”, or the “RAM clear processing” has been performed based on the start timing of the demonstration effect from being easily identified, and It is prevented that the pachinko machine 10 for which the “setting confirmation operation”, the “setting change operation”, or the “RAM clear processing” has been performed based on the deviation of the types of the demonstration effect and the standby symbol display is easily identified. ..

According to this embodiment described in detail above, the following excellent effects are exhibited.

While it is possible to execute a plurality of types of demonstration effects and standby symbol displays on the symbol display device 41, it is possible to align the timing at which the demonstration effects are started in the plurality of pachinko machines 10 where the supply of operating power is started at the same time, It is possible to align the types of demonstration effects to be executed at the timing. In addition, it is possible to align the timing at which the standby symbol display is started in the plurality of pachinko machines 10 and to align the types of standby symbol display to be executed at the timing. As a result, it is possible to give a sense of unity to the demonstration effect and the standby symbol display in the plurality of pachinko machines 10 and increase the player's interest in the pachinko machines 10.

When the supply of operating power to the plurality of pachinko machines 10 is started at the same time, and “setting confirmation operation”, “setting change operation” for some of the plurality of pachinko machines 10 are performed, Alternatively, when the "RAM clear operation" is performed, the "demonstration start operation" and the type of the demonstration effect in the pachinko machine 10 for which the "setting confirmation operation", the "setting change operation" and the "RAM clear operation" have not been performed. It is possible to align the start timing of demo demonstration and the type of demonstration demonstration in the pachinko machine 10 for which the "setting confirmation operation", "setting change operation" or "RAM clear operation" has been performed. As a result, the pachinko machine 10 for which the “setting confirmation operation”, the “setting change operation”, or the “RAM clear operation” has been performed can be easily identified based on the start timing of the demonstration effect and the deviation of the type of the demonstration effect. It can be prevented.

<82nd Embodiment>
This embodiment is different from the 35th embodiment in that data indicating the state of the base value with respect to the normal range of the base value is output to the outside of the pachinko machine 10. The configuration different from that of the 35th embodiment will be described below. The description of the same configuration as the thirty-fifth embodiment is basically omitted.

As already described in the thirty-fifth embodiment, the base value is the total number of game balls discharged from the game area PA in a situation that is neither the open/close execution mode due to the big hit result nor the high frequency support mode (that is, the game area). It is the ratio of the total payout number of game balls to the total number of game balls supplied to the PA. The base value is calculated as a decimal number to the second decimal place in the base value calculation process (step S8601 of the result calculation process (FIG. 130)) as in the 35th embodiment. As described above with reference to FIG. 126 in the thirty-fifth embodiment, the work area 223 for non-specific control is provided with the calculation result storage area 234, and the calculation result storage area 234 has the latest base. The current area 311 in which the value is stored, the first history area 312 in which the final base value in the previous calculation period is stored, and the first base area 312 in which the final base value in the previous calculation period is stored. A second history area 313 and a third history area 314 in which the final base value in the calculation period three times before is stored are provided.

In the present embodiment, a numerical value range of "0.30" to "0.40" is set as the normal base range which is the normal range of the base value assumed at the design stage. When the base value falls below the lower limit (0.30) of the normal base range, it is necessary to perform maintenance to adjust the state of the nails 24b scrambled on the game board 24, and the base value is normal to the base. If the upper limit of the range (0.40) is exceeded, it is necessary to confirm whether or not there is an action that illegally raises the total payout number of game balls.

In the present embodiment, the representative value data is output to the outside of the pachinko machine 10 as the representative value data that makes it possible to grasp the state of the base value with respect to the normal base range (0.30 to 0.40). The representative value when the base value is within the numerical range of "0" to "0.99" is the first decimal place of the base value. When the base value is within the numerical range of "0" to "0.99", the same base value is used even if the second decimal point is different if the first decimal point is the same. The representative value data of is output. The representative value when the base value is "1.00" is "9". The representative value data is 4-bit numerical information, and specifically, is any numerical information of “0000” to “1001” in binary notation (“0” to “9” in decimal notation).

FIG. 295(a) is an explanatory diagram illustrating a configuration for externally outputting the representative value data in the present embodiment. As shown in FIG. 295(a), the MPU 62 is provided with a main output terminal TA1 for outputting the representative value data from the main CPU 63, and the external terminal board 97 is provided with the main output terminal TA1. An external receiving terminal TB1 for receiving the output representative value data is provided. The main output terminal TA1 and the external reception terminal TB1 are electrically connected using the external output signal line group 561. The external output signal line group 561 includes four data signal lines for transmitting representative value data in units of 4 bits, and data acquisition timing in an external device (a data display DI to be described later) that receives the representative value data. And a single control signal line for transmitting a pulse-shaped control signal that enables the user to grasp. The main CPU 63 outputs the pulse-shaped control signal to the control signal line after the 4-bit representative value data is output to the four data signal lines. This makes it possible to transmit the 4-bit unit representative value data to the external terminal board 97 at once.

The external terminal board 97 is provided with an external output terminal TC1 for externally outputting the representative value data received by the external receiving terminal TB1. The external output terminal TC1 can be connected to an external device such as a data display DI provided outside the pachinko machine 10. The data display DI is provided in one-to-one correspondence with the pachinko machine 10. The data display DI has a display surface capable of displaying a one-digit number, and a representative value based on the representative value data received from the pachinko machine 10 by the data display DI is displayed on the display surface. The manager of the gaming hall can grasp the representative value of the pachinko machine 10 based on the display of the data display DI.

The hall computer HC is electrically connected to a data display DI which is provided in a one-to-one correspondence with a large number of pachinko machines installed in the game hall. The data display DI outputs information including the representative value data received from the pachinko machine 10 and the identifier data of the data display DI to the hall computer HC. The hall computer HC identifies the pachinko machine 10 based on the identifier data received from the data display DI, and the representative values (“0” to Understand any number of "9"). This allows the hall computer HC to grasp the representative value output from the pachinko machine 10 to the outside.

By making it possible to grasp the representative value externally output from the pachinko machine 10 in the hall computer HC, it is possible to grasp the state of the base value for the normal base range (0.30 to 0.40). Specifically, when the representative value is “0” to “2”, it can be understood that the base value is below the lower limit (0.30) of the normal base range. When the representative value is "5" to "9", it can be grasped that the base value is in a state of greatly exceeding the upper limit (0.40) of the normal base range. Further, since the representative value output from the pachinko machine 10 can be monitored based on the display of the representative value on the data display DI, the representative value output from the pachinko machine 10 can be easily grasped. Therefore, the burden of monitoring the representative value by the manager of the game hall is reduced.

By making it possible to grasp that the base value is below the lower limit (0.30) of the base normal range (0.30 to 0.40) in the hall computer HC and the data display DI, the manager of the gaming hall can know. On the other hand, it is possible to give an opportunity for maintenance to adjust the state of the nails 24b scolded on the game board 24 in the pachinko machine 10. Further, by making it possible to grasp that the base value is much higher than the upper limit (0.40) of the base normal range in the hall computer HC and the data display DI, it is possible to inform the manager of the game hall of the game ball. It is possible to give an opportunity to confirm whether or not there is an action that illegally increases the total payout amount.

When the base value is out of the normal base range (0.30 to 0.40) and is in an abnormal state, based on the representative value data of the pachinko machine 10 received by the hall computer HC and the data display DI, It is possible to grasp the degree of abnormality in the base value. Specifically, when the representative value indicated by the received representative value data is “2” or less, the smaller the representative value is, the larger the base value in the current area 311 is from the normal base range, and the early response is required. Understand what is needed. Further, when the representative value indicated by the representative value data of the pachinko machine 10 received by the hall computer HC and the data display DI is “5” or more, the larger the representative value, the more the base value in the current area 311 becomes the base normal range. It can be understood that there is a large deviation from the above, and it is necessary to take an early action.

FIG. 295(b) is an explanatory diagram for explaining a storage area for external output of representative value data in the work area 221 for specific control. As shown in FIG. 295(b), a representative value data counter 562 is provided in the work area 221 for specific control. The representative value data counter 562 has a 4-bit data capacity, and the representative value data counter 562 stores 4-bit numerical information as representative value data.

Externally output the last two digits of the base value (the first decimal place and the second decimal place) as data for making it possible to grasp the state of the base value for the normal base range (0.30 to 0.40). In this configuration, it is necessary to output the 8-bit numerical information to the outside, and in the configuration that outputs the entire base value (1's place, 1st decimal place and 2nd decimal place), the 12-bit numerical information is outputted externally. Need to output. On the other hand, in the present embodiment, only 4-bit numerical information indicating a representative value (one of the numbers “0” to “9” corresponding to the base value) is externally output to the data display DI as the representative value data. This is the configuration. As a result, it is possible to reduce the number of signal lines for outputting the data that enables the state of the base value with respect to the normal range of the base from the MPU 62 to the external terminal board 97 by parallel communication, and to perform the specific control. It is possible to reduce the storage capacity of the work area 221 for storing the data. Further, it is possible to output the representative value data to the data display unit DI and the hall computer HC, which are set to have a small storage capacity for receiving and storing the data, and to output the representative value data to one digit. It is possible to connect the pachinko machine 10 to the data display DI capable of displaying only the numbers and output the representative value data to the outside.

Next, a specific processing configuration for externally outputting the representative value data will be described. FIG. 296 is a flowchart showing an external information setting process executed by the main CPU 63. The external information setting process is executed in step S8918 of the first timer interrupt process (FIG. 133) in the 35th embodiment. Further, the processing of steps SJ401 to SJ406 in the external information setting processing is executed by using the program for specific control and the data for specific control in the main CPU 63.

In the external information setting process, it is first determined whether or not "1" is set in the calculation initial flag provided in the work area 223 for non-specific control (step SJ401). Similar to the 35th embodiment, the calculation initial flag is discharged from the game area PA in a situation where the base value calculation period is newly started and the open/close execution mode or the high frequency support mode depending on the jackpot result is neither. A flag for the main CPU 63 to specify whether or not the total number of game balls (that is, the total number of game balls supplied to the game area PA) has reached the initial reference number (specifically, 6000). Is.

When it is determined in step SJ401 that the calculation initial flag is not set to "1", neither the open/close execution mode by the jackpot result nor the high-frequency support mode has been set since the base value calculation period was newly started. In a situation, it means that the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) has reached the initial reference number (specifically, 6000 pieces). , And the process for externally outputting the representative value data to the data display DI via the external terminal board 97 (the processes of steps SJ402 to SJ405).

Specifically, the representative value data counter 562 in the specific control work area 221 is cleared to "0" (step SJ402). After that, the current base value is grasped by referring to the current area 311 (FIG. 126) in the calculation result storage area 234 (step SJ403). As described above, the base value is a decimal number to the second decimal place. Thereafter, the representative value data corresponding to the base value grasped in step SJ403 is set in the representative value data counter 562 (step SJ404). Specifically, when the base value grasped in step SJ403 is within the numerical range of “0” to “0.99”, the numerical information indicating the first decimal place of the base value is used as the representative value. In addition to setting as data, when the base value grasped in step SJ403 is "1.00", numerical information of "9" is set as representative value data. As a result, the representative value data counter 562 is set to the state in which the 4-bit representative value data corresponding to any of the numbers “0” to “9” is set.

Then, the external output process of the representative value data is executed (step SJ405). In the external output processing of the representative value data, after the 4-bit representative value data is output to the four data signal lines in the external output signal line group 561, the control signal in the external output signal line group 561 is controlled. Output a pulsed control signal to the line. Accordingly, the 4-bit unit representative value data is externally output to the data display DI via the external terminal board 97. The data display DI acquires the representative value data in 4-bit units output to the four data signal lines at the timing of receiving the pulsed control signal. As described above, the data display DI displays the representative value based on the representative value data received from the pachinko machine 10. Further, the data display DI outputs information including the representative value data received from the pachinko machine 10 and the identifier data of the data display DI to the hall computer HC. The manager of the game hall can confirm the representative value of the pachinko machine 10 on the data display DI and the hall computer HC.

If an affirmative decision is made in step SJ401, or if the processing of step SJ405 has been carried out, other external output processing is executed (step SJ406), and this external information setting processing ends. In other external output processing in step SJ406, information indicating that the opening/closing execution mode is in effect, information indicating that the support mode is in the high-frequency support mode, information indicating that one game time has ended, a predetermined number Information indicating that (for example, 100) game balls have been discharged from the game area PA through any one of the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first operating opening 33, and the second operating opening 34, A process for externally outputting to the hall computer HC information indicating that a game ball has entered the first operating port 33 and information indicating that a game ball has entered the second operating port 34 is executed.

As described above, since the base value calculation period is newly started, the total number of game balls discharged from the game area PA in a situation that is neither the open/close execution mode due to the jackpot result nor the high frequency support mode (that is, the game area PA). If the total number of game balls supplied to the) has reached the initial reference number (specifically 6000), the representative value of the base value in the current area 311 (the first decimal place of the base value) Is output to the data display unit DI via the external terminal board 97.

Assuming that the data that enables the state of the base value for the normal base range (0.30 to 0.40) is not output to the outside of the pachinko machine 10, the base for the normal base range (0.30 to 0.40) is set. When trying to grasp the state of the value, the manager of the gaming hall moves to the place where the pachinko machine 10 is installed in the gaming hall and moves the gaming machine body 12 to the front of the pachinko machine 10 with respect to the outer frame 11. It is necessary to open and open the display screens of the first to fourth notification display devices 201 to 204. Moreover, when trying to grasp the state of the base value for the normal base range (0.30 to 0.40) of the plurality of pachinko machines 10 set in the game hall, it is necessary to perform the work for each machine. The monitoring burden on the manager of the game hall will be heavy. On the other hand, in the present embodiment, the representative value data indicating the representative value of the base value (any one of the numbers “0” to “9” corresponding to the base value) is externally output to the data display DI. is there. In addition, as described above, the data display DI outputs information including the representative value data received from the pachinko machine 10 and the identifier data of the data display DI to the hall computer HC. Thereby, the state of the base value with respect to the normal base range can be grasped in the data display DI and the hall computer HC. When a plurality of pachinko machines 10 are installed, the hall computer HC can collectively grasp the representative values of the plurality of pachinko machines 10. As a result, it is possible to reduce the monitoring burden on the manager of the game hall.

Since the base value calculation period was newly started, the total number of game balls discharged from the game area PA (that is, supplied to the game area PA in a situation where neither the open/close execution mode due to the jackpot result nor the high-frequency support mode is used). If the total number of game balls has not reached the initial reference number (specifically, 6000), the representative value data is not output to the outside. Immediately after the start of the calculation period, since there is little information on the game history for calculating the base value, the actual measurement value of the base value may be a value that is largely outside the theoretical value range of the base value. Since the external output of the representative value data is not executed in the state where the information of the game history for calculating the base value is not sufficient, the data display DI and the hall computer HC are the representative value data based on the unstable base value. Is prevented from being received. This prevents frequent maintenance of adjusting the state of the nails 24b scrambled on the game board 24 and confirmation of the presence or absence of an action that illegally raises the total payout number of game balls. Has been done.

Next, with reference to the time chart of FIG. 297, the manner in which the abnormality of the base value can be grasped based on the representative value data externally output to the data display DI will be described. FIG. 297(a) shows the timing when the abnormality of the base value can be grasped in the hall computer HC and the data display DI, and FIG. 297(b) shows the period in which the main CPU 63 outputs the base value “3” to the outside. 297(c) shows the period during which the base CPU 63 outputs the base value of "2" to the outside, and FIG. 297(d) shows the opening/closing according to the jackpot result after the base value calculation period is newly started. The initial reference number (specifically, 6000) is the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) in a state that is neither the execution mode nor the high frequency support mode. 297 (e) is shown, and FIG. 297(e) is discharged from the game area PA in a situation where neither the opening/closing execution mode by the jackpot result nor the high-frequency support mode has occurred since the base value calculation period was newly started. The timing at which the total number of played game balls (that is, the total number of game balls supplied to the game area PA) reaches the shift reference number (specifically, 60000) is shown.

As shown in FIG. 297(d) at the timing of t1, since the base value calculation period is newly started, the game discharged from the game area PA in a situation where neither the open/close execution mode by the jackpot result nor the high frequency support mode is present. When the total number of balls (that is, the total number of game balls supplied to the game area PA) reaches the initial reference number (specifically, 6000), external output of the representative value data to the data display DI is started. It As shown in FIG. 297(b), the representative value data indicating the representative value of "3" is externally output at the timing of t1. As a result, in the hall computer HC and the data display DI, the decimal point of the current base value of the pachinko machine 10 is "3", and maintenance and confirmation of illegal acts are unnecessary. It becomes possible to grasp.

Then, as shown in FIGS. 297(b) and 297(c), the representative value of the representative value data externally output to the data display DI changes from "3" to "2" at the timing of t2. As a result, the representative value indicated by the representative value data received by the hall computer HC and the data display DI also changes from "3" to "2". As shown in FIG. 297(a), it becomes possible to grasp the abnormality of the base value in the pachinko machine 10 in the hall computer HC and the data display DI at the timing of t2. Specifically, the current base value of the pachinko machine 10 is below the lower limit (0.30) of the base normal range (0.30 to 0.40), and the nail 24b scrambled on the game board 24. It is possible to understand that maintenance is required to adjust the state and so on.

Then, as shown in FIG. 297(e), the base value calculation period is newly started at the timing of t3, and the game area PA is discharged in a situation where neither the open/close execution mode according to the jackpot result nor the high frequency support mode is present. When the total number of played game balls (that is, the total number of game balls supplied to the game area PA) reaches the shift reference number (specifically, 60000), the data shift process (result calculation process (FIG. 130)) is performed. Step S8607) is executed. In the data shift process, the information stored in the current state area 311, the first history area 312, the second history area 313, and the third history area 314 in the calculation result storage area 234 is the same as in the 35th embodiment. After shifting in the order of the second history area 313→the third history area 314, the first history area 312→the second history area 313, the current area 311→the first history area 312, the current area 311 is cleared to “0”. As a result, as shown in FIG. 297(d), the game discharged from the game area PA in a situation where the base value calculation period is newly started and the open/close execution mode or the high frequency support mode depending on the jackpot result is neither The total number of balls (that is, the total number of game balls supplied to the game area PA) has not reached the initial reference number (specifically, 6000), and as shown in FIG. 297(c), the t3 is concerned. The external output of the representative value data ends at the timing.

According to this embodiment described in detail above, the following excellent effects are exhibited.

When the base value in the current area 311 is within the numerical range of “0” to “0.99”, 4-bit numerical information indicating the first decimal place of the base value is displayed as representative value data. When the base value in the current area 311 is “1.00”, 4-bit numerical information indicating “9” as the representative value data is externally output to the data display DI. .. The data display DI outputs information including the representative value data received from the pachinko machine 10 and the identifier data of the data display DI to the hall computer HC. Therefore, the state of the base value with respect to the normal base range (0.30 to 0.40) can be grasped based on the representative value indicated by the representative value data received by the hall computer HC and the data display DI. .. Further, the hall computer HC can collectively grasp the representative values of the plurality of pachinko machines 10. As a result, it is possible to reduce the monitoring load of the game hall manager, which is necessary for managing the base value of the pachinko machine 10.

Since the 4-bit representative value data is externally output to the data display DI, the numerical information indicating the last two digits of the base value or the numerical information enabling the entire base value to be grasped is externally output to the data display DI. Compared with the output configuration, the data amount of the data that makes it possible to grasp the state of the base value for the normal base range (0.30 to 0.40) is reduced. As a result, it is possible to reduce the number of signal lines required to output the data from the MPU 62 to the external terminal board 97 by parallel communication, and to store the data in the work area 221 for specific control. It is possible to reduce the storage capacity for storing. Further, it is possible to output the representative value data to the data display unit DI and the hall computer HC, which are set to have a small storage capacity for receiving and storing the data, and to output the representative value data to one digit. It is possible to connect the pachinko machine 10 to the data display DI capable of displaying only the numbers and output the representative value data to the outside.

In the configuration in which the normal base range is set to the numerical range of “0.30” to “0.40”, the base value in the current area 311 is within the numerical range of “0” to “0.99” In the data display unit DI, the representative value data having the first decimal place of the base value as a representative value is output to the outside, and when the base value in the current area 311 is “1.00”, the data is displayed. Representative value data having “9” as a representative value is externally output to the display unit DI. Accordingly, when the representative value indicated by the representative value data received by the hall computer HC and the data display DI is “2” or less, the current base value of the pachinko machine 10 is the base normal range (0.30 to 0.40). ) Is below the lower limit (0.30), and when the representative value indicated by the representative value data received by the hall computer HC and the data display DI is “5” or more, it is a pachinko machine. It is possible to understand that the current base value of the machine 10 is in a state of greatly exceeding the upper limit (0.40) of the normal base range (0.30 to 0.40). Further, when the representative value indicated by the representative value data received by the hall computer HC and the data display DI is “2” or less, the smaller the representative value is, the larger the base value in the current area 311 is from the normal base range. Therefore, it is possible to grasp that it is necessary to take an action at an early stage, and when the representative value indicated by the representative value data received by the hall computer HC and the data display DI is “5” or more, The larger the representative value is, the larger the base value in the current area 311 is from the normal range of the base, and it can be grasped that it is necessary to take an early action.

Since the base value calculation period was newly started, the total number of game balls discharged from the game area PA (that is, supplied to the game area PA in a situation where neither the open/close execution mode due to the jackpot result nor the high-frequency support mode is used). If the total number of game balls has not reached the initial reference number (specifically, 6000), the representative value data is not output to the outside. The representative value data based on the unstable base value of the hall computer HC and the data display DI due to the configuration in which the external output of the representative value data is not executed when the information of the game history for calculating the base value is insufficient. Is prevented from being received. This prevents frequent maintenance of adjusting the state of the nails 24b scrambled on the game board 24 and confirmation of the presence or absence of an action that illegally raises the total payout number of game balls. Has been done.

The time interval at which the representative value data is externally output may be a predetermined time interval (for example, 10 minutes interval). Specifically, when it is determined in step SJ401 of the external information setting process (FIG. 296) that the operation initial flag is not set to "1", the previous external output process of the representative value data (step SJ405) is executed. Then, the external output process (step SJ405) of the representative value data is executed on condition that a predetermined time (for example, 10 minutes) has elapsed. As a result, the abnormality of the base value can be grasped based on the display of the representative value on the data display DI within a predetermined time (for example, 10 minutes) after the abnormality of the base value occurs, and the outside of the representative value data can be grasped. It is possible to reduce the execution frequency of the output process (step SJ405).

Further, in place of the configuration in which the representative value data is externally output to the data display DI by parallel communication, the configuration may be such that the representative value data is externally output to the data display DI by serial communication. By adopting a configuration in which the representative value data is externally output by serial communication, the number of signal lines for outputting the representative value data from the MPU 62 to the external terminal board 97 can be reduced. As already described in the 82nd Embodiment, the configuration is such that the 4-bit unit representative value data is externally output, so that the numerical information indicating the last two digits of the base value or the numerical information indicating the entire base value can be displayed. Compared with the configuration for external output, the data capacity of data for making it possible to grasp the state of the base value for the normal base range (0.30 to 0.40) is reduced. As a result, the time required for externally outputting the data by serial communication is shortened.

Further, instead of the representative value data, the base value data that allows the entire base value to be grasped may be externally output to the data display DI. Specifically, the base value data is any numerical value of "0" to "100" obtained by multiplying the base value, which is any numerical value information of "0" to "1.00", by "100". It is 7-bit unit data indicating information. The data display DI outputs information including the base value data received from the pachinko machine 10 and the identifier data of the data display DI to the hall computer HC. Therefore, it is possible to grasp the entire base value of the pachinko machine 10 on the hall computer HC and the data display DI. When the base value data is the numerical information of “0” to “29”, the game hall manager is given an opportunity to perform maintenance for adjusting the state of the nails 24b scolded on the game board 24. Can be given. In addition, when the base value data is "41" to "100", it is possible to give the manager of the game hall an opportunity to confirm whether or not there is an action that illegally raises the total payout amount of the game balls. it can.

<83rd Embodiment>
In this embodiment, the structure of the data externally output to the data display DI is different from that of the 82nd embodiment. Hereinafter, the configuration different from that of the 82nd embodiment will be described. The description of the same configuration as the 82nd embodiment is basically omitted.

In the present embodiment, "0" to "0" are set as an abnormal range of the base value (hereinafter also referred to as a base abnormal range) that requires maintenance for adjusting the state of the nails 24b scrambled on the game board 24. The numerical range of ".29" is set. In the present embodiment, as the processing representative value data indicating the relationship between the base value and the base abnormal range (0 to 0.29) in the current area 311 (FIG. 126) of the calculation result storage area 234, the processing representative in units of 2 bits is used. The value data is externally output to the data display DI.

The base value is calculated as a decimal number to the second decimal place in the base value calculation process (step S8601 of the result calculation process (FIG. 130)) as in the 35th embodiment. The base value is any numerical value information of "0" to "1.00". If the base value in the current area 311 (Fig. 126) is within the numerical range of "0" to "0.29", the processing representative value is the number of the first decimal place of the base value and the current status. When the base value in the area 311 is within the numerical range of "0.30" to "1.00", it is a number of "3". The processed representative value data is 2-bit numerical information of any of "00" to "11" in binary notation (numerical information of any of "0" to "3" in decimal notation).

As described above in the 35th embodiment, the fraud detection process is executed in step 8905 of the first timer interrupt process (FIG. 133). In the present embodiment, in the fraud detection process, when any one of fraudulent radio wave detection, fraudulent magnetism detection, and abnormal vibration detection is performed, the work area 221 for specific control is provided. "1" is set to the game stop flag. As already described in the thirty-fifth embodiment, by setting the game stop flag to "1", a negative determination is made in step S (906) of the first timer interrupt processing (FIG. 133), In a state in which the processing in S8907 to step S8920 is not executed, that is, in a state in which the progress of the game is stopped, therefore, in a case where a fraud that raises the base value is performed due to an illegal radio wave, an illegal magnet, or an abnormal vibration, Can be dealt with by setting the progress of the game to be stopped.

On the other hand, the state in which the winning abnormality occurs due to the state of the nail 24b scrambled on the game board 24 is not detected by the fraud detection process in step S8905 of the first timer interrupt process (FIG. 133). .. In the present embodiment, the state of the nails 24b scrambled on the game board 24 based on that the machining representative value externally output from the pachinko machine 10 to the hall computer HC is “2” or less is a cause. It is possible to understand the state that the winning prize is abnormal. This makes it possible to grasp the abnormal state of the base value that is not detected by the fraud detection process in the hall computer HC.

FIG. 298(a) is a block diagram for explaining a configuration for externally outputting the processed representative value data in the present embodiment. As shown in FIG. 298(a), the MPU 62 is provided with a main output terminal TA2 for outputting the machining representative value data from the main CPU 63, and the external terminal board 97 is provided with the main output terminal TA2. An external side reception terminal TB2 for receiving the processed representative value data output from is provided. The main output terminal TA2 and the external reception terminal TB2 are electrically connected using the external output signal line group 563.

The external output signal line group 563 can grasp the data acquisition timing in two data signal lines for transmitting the processed representative value data in units of 2 bits and the data display DI that receives the processed representative value data. And one control signal line for transmitting a pulsed control signal. The main-side CPU 63 outputs a pulse-shaped control signal to the control signal line after the 2-bit processed representative value data has been output to the two data signal lines. Thereby, it is possible to transmit the processed representative value data in units of 2 bits to the external terminal board 97 at once.

The external terminal board 97 is provided with an external output terminal TC2 for externally outputting the processed representative value data received by the external receiving terminal TB2. The external output terminal TC2 can be connected to an external device such as a data display DI provided outside the pachinko machine 10. The data display DI has a display surface capable of displaying a one-digit number, and the processing representative value is displayed on the display surface based on the processing representative value data received from the pachinko machine 10 by the data display DI. The manager of the game hall can grasp the processing representative value of the pachinko machine 10 based on the display of the data display DI.

The data display DI outputs information including the machining representative value data received from the pachinko machine 10 and the identifier data of the data display DI to the hall computer HC. The hall computer HC identifies the pachinko machine 10 based on the identifier data received from the data display DI, and based on the machining representative value data received simultaneously with the identification data, the machining representative value (“0 ) To "3". The manager of the game hall can also grasp the machining representative value of the pachinko machine 10 also in the hall computer HC.

As described above, the base abnormal range is a numerical range of “0” to “0.29”. In the present embodiment, the base value is within the base abnormal range (0 to 0.29) based on the processing representative value indicated by the processing representative value data received by the hall computer HC and the data display DI, and the game board 24 It is possible to grasp whether or not the prize winning abnormality is caused due to the condition of the nail 24b scrambled in. Specifically, when the processing representative value is "0" to "2", the prize winning abnormality is caused by the state of the nail 24b scolded on the game board 24 or the like. It is possible to grasp that.

By making it possible to grasp that the base value has entered the base abnormal range (0 to 0.29) in the hall computer HC and the data display DI, it is possible for the manager of the game hall to play a pachinko machine. It is possible to give an opportunity for maintenance for adjusting the state of the nails 24b scrambled on the game board 24 in FIG. When the base value falls within the base abnormal range, the degree of abnormality of the base value should be grasped based on the machining representative value indicated by the machining representative value data received by the hall computer HC and the data display DI. You can Specifically, when the machining representative value is “2”, it is possible to understand that the base value is close to the upper limit (0.29) of the base abnormal range (0 to 0.29). When the processing representative value is "1" or "0", it can be understood that the abnormality in the base value is serious and prompt action is required.

FIG. 298(b) is an explanatory diagram for explaining the storage area for external output of the machining representative value data, which is provided in the work area 221 for specific control. As shown in FIG. 298(b), a work representative value data counter 564 is provided in the work area 221 for specific control. The machining representative value data counter 564 has a data capacity of 2 bits, and the machining representative value data counter 564 stores 2-bit numerical information as the machining representative value data.

Due to the configuration in which the 2-bit processed representative value data is externally output to the data display DI, the numerical information indicating the last two digits of the base value or the numerical information enabling the entire base value to be grasped is displayed on the data display DI. Compared with the configuration for external output, the amount of data that enables the state of the base value for the abnormal base range (0 to 0.29) to be grasped is reduced. As a result, it is possible to reduce the number of signal lines required to output the data from the MPU 62 to the external terminal board 97 by parallel communication, and to store the data in the work area 221 for specific control. It is possible to reduce the storage capacity for storing. Further, it is possible to externally output the machining representative value data to the data display DI and the hall computer HC which are set to have a small storage capacity for receiving and storing the data. The pachinko machine 10 can also be connected to the data display DI that can display only digit numbers, and the machining representative value data can be output to the outside.

Next, the external information setting process executed by the main CPU 63 will be described with reference to the flowchart of FIG. 299. The external information setting process is executed in step S8918 of the first timer interrupt process (FIG. 133) in the 35th embodiment. Further, the processing of steps SJ501 to SJ508 in the external information setting processing is executed using the program for specific control and the data for specific control in the main CPU 63.

In step SJ501, the same process as step SJ401 of the external information setting process (FIG. 296) in the 82nd embodiment is executed. Specifically, it is determined whether or not "1" is set in the calculation initial flag provided in the work area 223 for non-specific control (step SJ501). When it is determined in step SJ501 that "1" is not set in the calculation initial flag, neither the open/close execution mode according to the jackpot result nor the high frequency support mode has occurred since the base value calculation period was newly started. In a situation, it means that the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) has reached the initial reference number (specifically, 6000 pieces). , Processing for outputting the processing representative value data to the data display DI via the external terminal board 97 (processing of steps SJ502 to SJ507).

Specifically, the machining representative value data counter 564 in the work area 221 for specific control is cleared to "0" (step SJ502). Thereafter, the current base value is grasped by referring to the current area 311 (FIG. 126) in the calculation result storage area 234 (step SJ503).

Then, it is determined whether or not the base value grasped in step SJ503 is "0.30" or more (step SJ504), and when the base value is "0.30" or more (step SJ504: YES). Sets numerical information of "3" ("11" in binary notation) to the machining representative value data counter 564 in the work area 221 for specific control (step SJ505). On the other hand, when a negative determination is made in step SJ504, the first decimal place numerical value (“0” to “2” numerical information (binary notation “00” in the current base value grasped in step SJ504. To numerical value information of 10)) is directly set in the machining representative value data counter 564 (step SJ506).

When the process of step SJ505 is performed or the process of step SJ506 is performed, the external output process of the machining representative value data is executed (step SJ507). In the external output processing of the processed representative value data, after the 2-bit processed representative value data is output to the two data signal lines in the external output signal line group 563, the external output signal line group 563 is processed. A pulsed control signal is output to the control signal line. As a result, the processing representative value data in units of 2 bits is externally output to the data display DI via the external terminal board 97. The data display DI acquires the processing representative value data in 2-bit units output to the two data signal lines at the timing of receiving the pulsed control signal. As described above, the data display DI displays the processed representative value based on the representative value data received from the pachinko machine 10. Further, the data display DI outputs information including the processed representative value data received from the pachinko machine 10 and the identifier data of the data display DI to the hall computer HC. The manager of the game hall can confirm the machining representative value of the pachinko machine 10 on the data display DI and the hall computer HC.

If an affirmative decision is made in step SJ501, or if the processing of step SJ507 has been carried out, other external output processing is executed (step SJ508), and this external information setting processing ends. In other external output processing, the information indicating that the open/close execution mode is in effect and the support mode are the same as the other external output processing (step SJ406) in the external information setting processing (FIG. 296) of the 82nd embodiment. Information indicating that the high frequency support mode is in progress, information indicating that one game time has ended, a predetermined number (for example, 100) of game balls have an outlet 24a, a general winning opening 31, a special electric winning device 32, Information indicating that the game ball is discharged from the game area PA through either the first operating port 33 or the second operating port 34, information indicating that a game ball has entered the first operating port 33, and the second operating port 34 A process for externally outputting to the hall computer HC information indicating that a game ball has entered is executed.

According to this embodiment described in detail above, the following excellent effects are exhibited.

When the base value in the current area 311 (FIG. 126) of the calculation result storage area 234 is within the numerical range of “0” to “0.29”, numerical information indicating the first decimal place of the base value. Is externally output to the data display DI as processing representative value data, and when the base value is within the numerical range of "0.30" to "1.00", numerical information of "3" is processing representative. The value data is externally output to the data display DI. The data display DI outputs information including the machining representative value data received from the pachinko machine 10 and the identifier data of the data display DI to the hall computer HC. Therefore, the base value is within the base abnormal range (0 to 0.29) based on the processing representative value indicated by the processing representative value data received by the hall computer HC and the data display DI, and is scolded on the game board 24. It is possible to grasp whether or not the winning abnormality is caused due to the state of the nail 24b being held. Further, the hall computer HC can collectively grasp the processing representative values of the plurality of pachinko machines 10. As a result, it is possible to reduce the monitoring load of the game hall manager, which is necessary for managing the base value of the pachinko machine 10.

When the machining representative value indicated by the machining representative value data received by the hall computer HC and the data display DI is "0" to "2", it is caused by the state of the nail 24b scolded on the game board 24 and the like. Therefore, it is possible to understand that the prize winning abnormality is occurring. As a result, it is possible to recognize the occurrence of a prize abnormality that is not detected in the fraud detection process (step 8905 of the first timer interrupt process (FIG. 133)). By making it possible to grasp that the base value is in the base abnormal range in the hall computer HC and the data display DI, the game hall manager is instructed to the game board 24 in the pachinko machine 10. It is possible to give an opportunity for maintenance to adjust the state and the like of the installed nails 24b.

Based on the machining representative value indicated by the machining representative value data received by the hall computer HC and the data display DI, the degree of abnormality of the base value can be grasped. Specifically, when the machining representative value is “2”, it is possible to understand that the base value is close to the upper limit (0.29) of the base abnormal range (0 to 0.29). When the processing representative value is "1" or "0", it can be understood that the abnormality in the base value is serious and prompt action is required.

Due to the configuration in which the 2-bit processed representative value data is externally output to the data display DI, the numerical information indicating the last two digits of the base value or the numerical information enabling the entire base value to be grasped is displayed on the data display DI. Compared with the configuration for external output, the amount of data that enables the state of the base value for the abnormal base range (0 to 0.29) to be grasped is reduced. As a result, it is possible to reduce the number of signal lines required to output the data from the MPU 62 to the external terminal board 97 by parallel communication, and to store the data in the work area 221 for specific control. It is possible to reduce the storage capacity for storing. Further, it is possible to externally output the machining representative value data to the data display DI and the hall computer HC which are set to have a small storage capacity for receiving and storing the data. The pachinko machine 10 can also be connected to the data display DI that can display only digit numbers, and the machining representative value data can be output to the outside.

Since the base value calculation period was newly started, the total number of game balls discharged from the game area PA (that is, supplied to the game area PA in a situation where neither the open/close execution mode due to the jackpot result nor the high-frequency support mode is used). When the total number of game balls does not reach the initial reference number (specifically, 6000), the processing representative value data is not externally output. The processing representative value data is not output externally when the game history information for calculating the base value is not sufficient, so that the hall computer HC and the data display DI are processing representatives based on the unstable base value. Receiving value data is prevented. This prevents frequent maintenance for adjusting the state of the nails 24b scrambled on the game board 24.

In addition, when the base value is within the numerical range of “0” to “0.29”, the first decimal point of the base value is set as the processing representative value, and the base value is from “0.30” to Instead of the processing representative value setting mode in which the processing representative value is set to "3" when it is within the numerical value range of "1.00", the base value is a numerical value range of "0" to "0.29". If it is within the range, "1" is set as the machining representative value, and if the base value is within the numerical range of "0.41" to "1.00", then "2" is set as the machining representative value. The setting mode may be set such that when the base value is within the numerical range of “0.30” to “0.40”, “3” is set as the processing representative value. Accordingly, when the normal range of the base value in the design stage is set to “0.30” to “0.40”, the base value is set to the normal range (0. It is possible to externally output the machining representative value data in such a manner that an abnormal state smaller than 30 to 0.40) and an abnormal state whose base value is larger than the normal range can be distinguished.

Further, when the base value is within the base abnormal range (0 to 0.29), the numerical information of "1" is externally output to the data display DI, and the base value is the base abnormal range (0 to 0.29). When it is not entered, the numerical information of "0" may be externally output to the data display DI. Thus, maintenance for adjusting the state of the nails 24b scrambled on the game board 24 in the hall computer HD and the data display DI while suppressing the data amount of the numerical information externally output to the data display DI to 1 bit. It is possible to grasp whether or not is necessary.

Further, the time interval at which the processing representative value data is externally output may be a predetermined time interval (for example, 10 minutes interval). Specifically, when it is determined in step SJ501 of the external information setting process (FIG. 299) that the calculation initial flag is not set to "1", the previous processing representative value data external output process (step SJ507) is executed. An external output process (step SJ507) of the machining representative value data is executed on condition that a predetermined time (for example, 10 minutes) has elapsed from the execution. Thereby, based on the display of the machining representative value on the data display DI within a predetermined time (for example, 10 minutes) after the occurrence of the abnormal state in which the base value falls within the base abnormal range (0 to 0.29). It is possible to reduce the execution frequency of the external processing of processing representative value data (step SJ507) while making it possible to grasp the abnormal state.

Further, in place of the configuration in which the processing representative value data is externally output to the data display DI by parallel communication, the processing representative value data may be externally output to the data display DI by serial communication. With the configuration in which the processed representative value data is externally output by serial communication, the number of signal lines for outputting the representative value data from the MPU 62 to the external terminal board 97 can be reduced. As already described in the 83rd embodiment, the processing representative value data in 2-bit units is externally output, so that the numerical information indicating the last two digits of the base value or the numerical information indicating the entire base value is obtained. In comparison with the configuration for externally outputting, the data capacity of data for making it possible to grasp the state of the base value for the normal base range (0.30 to 0.40) is reduced. As a result, the time required for externally outputting the data by serial communication is shortened.

Further, instead of the configuration in which the base abnormal range is set to the numerical range of “0” to “0.29”, the abnormal base value is set to the numerical range of “0.41” to “1.00”. It may be configured to have. With this configuration, when the base value in the current area 311 is within the numerical range of “0” to “0.40” in the external information setting process (FIG. 299), the numerical information of “0” is output to the outside. If the base value in the current area 311 exceeds “0.40”, the numerical value information corresponding to the base value is externally output. Specifically, when the base value in the current area 311 is within the numerical range of “0.41” to “0.60”, the numerical information of “1” is output to the outside and the base value in the current area 311 is output. Is within the numerical range of “0.61” to “0.80”, numerical information of “2” is output to the outside, and the base value in the current area 311 is “0.81” to “1.00”. If it is within the numerical range of “”, the numerical information of “3” is output to the outside. As a result, while suppressing the data amount of the numerical information externally output from the pachinko machine 10 to the data display DI to 2 bits, whether or not there is an abnormal state in which the base value in the current area 311 exceeds “0.40”, It is possible to grasp the degree of abnormality when the value exceeds "0.40" on the hall computer HC and the data display DI.

<84th Embodiment>
This embodiment is different from the above-described 82nd embodiment in that a base value abnormality signal indicating a base value abnormality is externally output. Hereinafter, the configuration different from that of the 82nd embodiment will be described. The description of the same configuration as the 82nd embodiment is basically omitted.

The base value is calculated as a decimal number to the second decimal place in the base value calculation process (step S8601 of the result calculation process (FIG. 130)) as in the 35th embodiment. In the present embodiment, a numerical range of "0.35" to "0.40" is set as a normal base range that is a normal range of base values assumed at the design stage. "0.35" is set as the lower threshold of the normal base range, and "0.40" is set as the upper threshold of the normal base range. When the base value is lower than the lower threshold value (0.35) and when the base value is higher than the upper threshold value (0.40), an external device of a base value abnormality signal indicating abnormality of the base value (abnormality described later) External output to the alarm EI) is performed.

FIG. 300A is a block diagram for explaining the configuration for externally outputting the base value abnormality signal in this embodiment. As shown in FIG. 300(a), the MPU 62 is provided with a main output terminal TA3 for outputting a base value abnormality signal from the main CPU 63, and the external terminal board 97 is provided with the main output terminal TA3. An external receiving terminal TB3 for receiving the base value abnormal signal output from the external terminal is provided. The main output terminal TA3 and the external reception terminal TB3 are electrically connected to each other by using the data signal line LN5 and the clock signal line LN6. All of these signal lines LN5 to LN6 are signal lines for transmitting signals from the main CPU 63 to the external terminal board 97 by one-way communication.

A base value abnormality signal is transmitted from the main CPU 63 to the external terminal board 97 by serial communication using the data signal line LN5. In this case, each 1-bit division of the base value abnormality signal by serial communication is indicated by the clock signal transmitted from the main CPU 63 to the external terminal board 97 using the clock signal line LN6.

The external terminal board 97 is provided with an external output terminal TC3 for externally outputting the base value abnormality signal received by the external receiving terminal TB3. The external output terminal TC3 can be connected to an external device such as an abnormality alarm EI provided outside the pachinko machine 10. The abnormality alarm device EI is provided in one-to-one correspondence with the pachinko machine 10. The abnormality indicator EI includes a light emitting unit, and when the abnormality indicator EI receives the base value abnormality signal from the pachinko machine 10, the abnormality indicator EI causes the light emitting unit to emit light in a light emitting mode for notifying the abnormality of the base value. Notify the base value abnormality. The manager of the gaming hall can understand that the base value abnormality has occurred in the pachinko machine 10 based on the abnormality notification in the abnormality notification device EI.

The hall computer HC is electrically connected to an abnormality alarm device EI provided in a one-to-one correspondence with a large number of pachinko machines installed in the game hall. The abnormality notification device EI outputs information including the base value abnormality signal received from the pachinko machine 10 and the identifier data of the abnormality notification device EI to the hall computer HC. The hall computer HC identifies the pachinko machine 10 based on the identifier data received from the abnormality alarm EI, and grasps the abnormality of the base value in the pachinko machine 10 based on the base value abnormality signal received simultaneously with the identifier data. To do. When the hall computer HC receives the base value abnormality signal, the manager of the gaming hall can understand that the base value abnormality has occurred in the pachinko machine 10.

Based on the fact that the hall computer HC and the abnormality alarm EI have received the base value abnormality signal, it is possible to grasp that the base value is out of the normal range (0.35 to 0.40). By this, the manager of the game hall is given an opportunity for maintenance to adjust the state of the nails 24b scolded on the game board 24 in the pachinko machine 10 and the act of illegally increasing the total payout number of game balls. It is possible to give an opportunity to confirm the presence or absence of.

Since the base value abnormality signal is externally output to the abnormality annunciator EI, the abnormality of the base value can be grasped by comparison with the configuration in which the numerical information indicating the base value is externally output to the abnormality annunciator EI. The amount of data to be output to the outside is reduced. As a result, the time required to externally output the data for making it possible to grasp the abnormality of the base value by serial communication is shortened, and the storage capacity of the storage area for receiving and storing the data is set small. It is possible to notify the abnormality of the base value by connecting the pachinko machine 10 to the abnormality alarm device EI that is operating.

FIG. 300B is an explanatory diagram for explaining a storage area for externally outputting the base value abnormality signal, which is provided in the work area 221 for specific control. As shown in FIG. 300B, a base value abnormality flag 565 is provided in the work area 221 for specific control. The base value abnormality flag 565 is a flag that allows the main CPU 63 to know that an abnormality in the base value has occurred.

In the main CPU 63, the base value stored in the first history area 312 to the third history area 314 (FIG. 126) in the calculation result storage area 234 when the supply of the operating power to the main CPU 63 is started is the base normal range (0 .35-0.40). Further, after the supply of the operating power to the main CPU 63 is started, it is determined whether the base value in the current area 311 (FIG. 126) of the calculation result storage area 234 is within the normal base range. In these determinations, when the base value is above the upper threshold value (0.40) or when the base value is below the lower threshold value (0.35), it is determined that the base value is abnormal, “1” is set to the base value abnormality flag 565 in the work area 221 for specific control.

The main ROM 64 stores in advance a threshold table that is referred to when determining whether or not the base value is within the normal base range (0.35 to 0.40). FIG. 300C is an explanatory diagram for explaining the threshold value table 566. As shown in FIG. 300(c), in the threshold table 566, "0.40" is set as the upper threshold of the normal base value range, and "0.35" is set as the lower threshold of the normal base value range. It is set. Since the threshold value table 566 is stored in the main ROM 64 in advance, the main CPU 63 determines the presence/absence of an abnormality in the base value and the type of abnormality, and outputs the base value abnormality signal corresponding to the type of the abnormality in the base value. It is possible to externally output to the abnormality alarm EI.

In the present embodiment, an output trigger of the base value abnormality signal occurs every predetermined time (specifically, 1 hour) after the supply of the operating power to the main CPU 63 is started. When the base value abnormality flag 565 is set to "1", the main CPU 63 externally outputs the base value abnormality signal to the abnormality alarm device EI based on the occurrence of the output trigger of the base value abnormality signal. .. As a result, it is possible to detect the occurrence of the abnormality of the base value in the hall computer HC and the abnormality alarm EI within a predetermined time (specifically, 1 hour) after the abnormality of the base value occurs. it can.

Next, a specific processing configuration for externally outputting the base value abnormality signal will be described. FIG. 301 is a flowchart showing the external information setting process executed by the main CPU 63. The external information setting process is executed in step S8918 of the first timer interrupt process (FIG. 133) in the 35th embodiment. Further, the processing of steps SJ601 to SJ613 in the external information setting processing is executed by using the specific control program and the specific control data in the main CPU 63.

In the external information setting process, first, it is determined whether or not the base value abnormality flag 565 in the specific control work area 221 is set to "1" (step SJ601). When "1" is not set in the base value abnormality flag 565 (step SJ601: NO), it is determined whether or not "1" is set in the calculation initial flag in the work area 223 for non-specific control. (Step SJ602). Similar to the 35th embodiment, the calculation initial flag is discharged from the game area PA in a situation where the base value calculation period is newly started and the open/close execution mode or the high frequency support mode depending on the jackpot result is neither. A flag for the main CPU 63 to specify whether or not the total number of game balls (that is, the total number of game balls supplied to the game area PA) has reached the initial reference number (specifically, 6000). Is.

When it is determined in step SJ602 that "1" is not set in the calculation initial flag, neither the open/close execution mode according to the jackpot result nor the high-frequency support mode has been set since the base value calculation period was newly started. It means that the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) has reached the initial reference number (specifically, 6000) in the situation. In this case, the current base value is grasped by referring to the current area 311 (FIG. 126) in the calculation result storage area 234 (step SJ603).

Then, the threshold table 566 (FIG. 300(c)) is read from the main ROM 64 (step SJ604). Then, it is determined whether or not the base value grasped in step SJ603 exceeds the upper threshold value (0.40) set in the threshold value table 566 read in step SJ604 (step SJ605). When a negative determination is made in step SJ605, it is determined whether the base value grasped in step SJ603 is lower than the lower threshold value (0.35) set in the threshold value table 566 read in step SJ604. It is determined (step SJ606).

When an affirmative judgment is made in step SJ605 or when an affirmative judgment is made in step SJ606, that is, the base value in the current area 311 (FIG. 126) is out of the normal base range (0.35-0.40). If so, "1" is set to the base value abnormality flag 565 in the specific control work area 221 (step SJ607). As a result, when the output trigger of the base value abnormality signal occurs, the base value abnormality signal is externally output to the abnormality notification device EI.

If an affirmative determination is made in step SJ601, a negative determination is made in step SJ606, or if the processing of step SJ607 is performed, the base value timer counter provided in the work area 221 for specific control is provided. It is determined whether the value of has become "0" (step SJ608). The base value timer counter is a timer counter that allows the main CPU 63 to grasp the output trigger of the base value abnormality signal. Numerical information corresponding to one hour is set in the base value timer counter in step SJ609 described later and step SJ812 in the base value initial output process (FIG. 303) described later. The base value timer counter is updated by the timer update process (step S8910 of the first timer interrupt process (FIG. 133)). The value of the base value timer counter is decremented by 1 each time the timer updating process is executed. When the value of the base value timer counter is decremented by 1 and the value of the base value timer counter becomes “0”, an output trigger of the base value abnormality signal occurs. As described above, the main CPU 63 sends the base value abnormality signal to the abnormality alarm device EI based on the occurrence of the output of the base value abnormality signal when the base value abnormality flag 565 is set to "1". Output to external.

When it is determined in step SJ608 that the value of the base value timer counter is "0", numerical information corresponding to 1 hour is set in the base value timer counter (step SJ609). As described above, when the value of the base value timer counter becomes “0” and the output trigger of the base value abnormality signal occurs, the numerical information corresponding to one hour is set in the base value timer counter. As a result, the output trigger of the base value abnormality signal can be generated at a predetermined time interval (specifically, one hour interval).

After that, when "1" is set to the base value abnormality flag 565 in the work area 221 for specific control (step SJ610: YES), external output processing of the base value abnormality signal is executed (step SJ611). In the external output process of the base value abnormality signal, the main output terminal TA3 outputs the data signal line LN5 in the situation where a pulsed clock signal is output from the main output terminal TA3 of the MPU 62 to the clock signal line LN6. After raising the signal that has been set from LOW to HI, the signal is lowered from HI to LOW. As a result, the base value abnormality signal is externally output to the abnormality alarm EI via the external terminal board 97.

As described above, when the base value abnormality flag 565 is set to "1", the base value abnormality signal is externally output to the abnormality alarm device EI based on the occurrence of the output trigger of the base value abnormality signal. As described above, the abnormality alarm EI notifies the base value abnormality based on the reception of the base value abnormality signal from the pachinko machine 10. Further, the abnormality notification device EI outputs information including the base value abnormality signal received from the pachinko machine 10 and the identifier data of the abnormality notification device EI to the hall computer HC. The manager of the game hall can grasp the abnormality of the base value in the pachinko machine 10 on the hall computer HC and the abnormality alarm EI.

If an affirmative determination is made in step SJ602, a negative determination is made in step SJ608, a negative determination is made in step SJ610, or if the processing of step SJ612 is performed, other external output processing is performed. Is executed (step SJ613), and the external information setting process is ended. In the other external output processing in step SJ613, similar to the other external output processing (step SJ406) in the external information setting processing (FIG. 296) of the 82nd embodiment, information indicating that the open/close execution mode is set, Information indicating that the support mode is in the high-frequency support mode, information indicating that one game time has ended, a predetermined number (for example, 100) of game balls are the outlet port 24a, the general winning opening 31, the special electricity winning device. 32, information indicating that the first operation port 33 or the second operation port 34 has discharged from the game area PA, information indicating that the game ball has entered the first operation port 33, and the second operation A process for externally outputting information indicating that a game ball has entered the mouth 34 to the hall computer HC is executed.

As described above, since the base value calculation period is newly started, the total number of game balls discharged from the game area PA in a situation that is neither the open/close execution mode due to the jackpot result nor the high frequency support mode (that is, the game area PA). When the base value in the current area 311 exceeds the upper threshold value (0.40) in the state where the total number of game balls supplied to the player has reached the initial reference number (specifically, 6000), or the current state When the base value in the area 311 is below the lower threshold value (0.35), the base value abnormality flag 565 is set to "1".

By storing the threshold value table 566 in the main ROM 64 in advance, the main CPU 63 determines whether or not there is an abnormality in the base value. It is possible to output. The normal base range, which is the normal range of base values, may differ depending on the model of the pachinko machine. When the pachinko machine 10 is connected to the general-purpose abnormality notification device EI, if the base value itself of the pachinko machine 10 is externally output to the abnormality notification device EI, the abnormality notification device EI receives from the pachinko machine 10. It is not possible to immediately determine whether or not the base value is within the normal range of the pachinko machine 10. Further, also in the hall computer HC connected to the abnormality annunciators EI corresponding to a plurality of models having different base normal ranges, the base value received via the abnormality annunciator EI falls within the normal base range of the pachinko machine 10. Whether or not it cannot be immediately determined. On the other hand, in this embodiment, when the main CPU 63 determines that the base value is abnormal, the base value abnormality signal is externally output to the abnormality alarm EI. This makes it easy to determine whether or not the base value of the pachinko machine 10 is abnormal in the abnormality annunciator EI and the hall computer HC which receive the base value abnormality signal.

Since the base value calculation period was newly started, the total number of game balls discharged from the game area PA (that is, supplied to the game area PA in a situation where neither the open/close execution mode due to the jackpot result nor the high-frequency support mode is used). When the total number of game balls has not reached the initial reference number (specifically 6000), it is determined whether the base value is within the base normal range (0.35 to 0.40). Not done Immediately after the start of the calculation period, since there is little information on the game history for calculating the base value, the actual measurement value of the base value may be a value that is largely outside the theoretical value range of the base value. Since the external output of the base value abnormality signal is not executed in the state where the game history information for calculating the base value is insufficient, the hall computer HC and the abnormality alarm EI are based on an unstable base value. Reception of an abnormal signal is prevented. This prevents frequent maintenance of adjusting the state of the nails 24b scrambled on the game board 24 and confirmation of the presence or absence of an action that illegally raises the total payout number of game balls. Therefore, the reliability of the abnormal base value signal is improved.

A configuration in which the output trigger of the base value abnormality signal is generated at a predetermined time interval (specifically, one hour interval), and the base value abnormality signal is externally output under the condition that the generation trigger of the base value abnormality signal is generated as one condition. As a result, the number of times the base value abnormality signal is externally output (step SJ611) is reduced. When the base value in the current area 311 is out of the normal base range (0.35 to 0.40), the base value abnormality signal is output externally every predetermined time (specifically, every one hour). Can be output. As a result, it is possible to output the base value abnormality signal to a plurality of times while preventing the external output of the base value abnormality signal from being continuously executed in a short period of time.

Next, main processing in this embodiment executed by the main CPU 63 will be described with reference to the flowchart in FIG. Note that the processes of steps SJ701 to SJ726 in the main process are executed using the specific control program and specific control data in the main CPU 63.

In step SJ701 to step SJ702, the same processing as step S8801 to step S8802 in the main processing (FIG. 132) of the 35th embodiment is executed. After that, "1" is set to the startup processing flag provided in the work area 221 for specific control (step SJ703). As in the thirty-fifth embodiment, the startup flag is a power failure monitor among various processes set in the first timer interrupt process even if the first timer interrupt process (FIG. 133) is activated. The main CPU 63 specifies that the first timer interrupt process should be ended without executing the process for advancing the game while executing the process for updating various counters and the illegality monitoring. It is a flag for doing. As already described in the thirty-fifth embodiment, by setting the start-up processing flag to "1", the processing of steps S8907 to S8920 of the first timer interrupt processing (FIG. 133) is not executed. Become. Therefore, the external information setting process (FIG. 301) described above is not executed.

Then, in steps SJ704 to SJ715, the same processes as steps S8804 to S8815 in the main process (FIG. 132) of the 35th embodiment are executed. Similar to the 35th embodiment, when the reset button 68c is pressed at the start of supplying the operating power to the main CPU 63 (step SJ706: YES), the RAM clearing process is executed (step SJ716). The contents of the RAM clear process are the same as step S7915 of the main process (FIG. 114) in the 33rd embodiment. In the RAM clearing process, the work area for specific control except for the area (specifically, the set value counter) in which the setting value information indicating the setting state of the pachinko machine 10 is set in the work area 221 for specific control. 221 is cleared to “0” and the initial setting is executed. Therefore, when the RAM clear process (step SJ716) is executed, the base value abnormality flag 565 in the specific control work area 221 is also cleared to "0".

On the other hand, in the RAM clear process (step SJ716), the work area 223 for non-specific control is not cleared to "0". Therefore, even if the RAM clearing process is executed, the most recent base value stored in the current state area 311 of the calculation result storage area 234 in the work area 223 for non-specific control and the first history area 312 are stored. The final base value in the calculation period one time before, the final base value in the calculation period two times before stored in the second history area 313, and the three times stored in the third history area 314. The final base value in the previous calculation period is not cleared to "0".

In steps SJ717 to SJ719, the same processing as steps S8817 to S8819 in the main processing (FIG. 132) of the 35th embodiment is executed. When the processing of step SJ712 is performed, when the negative determination is performed at step SJ713, when the negative determination is performed at step SJ714, when the processing of step SJ715 is performed, and when the negative determination is performed at step SJ717. If a negative determination is made in step SJ718, or if the process of step SJ719 is performed, the base value initial output process is executed (step SJ720). In the base value initial output process, the past base values stored in the first history area 312 to the third history area 314 (FIG. 126) in the calculation result storage area 234 are in the normal base range (0.35 to 0.40). ), the base value abnormality signal is externally output to the abnormality alarm EI. The details of the base value initial output process will be described later.

After the base value initial output processing is executed in step SJ720, the startup processing flag in the specific control work area 221 is cleared to "0" (step SJ721). By clearing the start-up processing flag "0", the state where the processing for advancing the game is not executed is canceled even if the first timer interrupt processing (FIG. 133) is started. As a result, the external state setting process (FIG. 301) described above is executed when the first timer interrupt process (FIG. 133) is activated.

Then, in steps SJ722 to SJ726, the same processes as steps S8821 to S8825 of the main process (FIG. 132) in the thirty-fifth embodiment are executed.

In the present embodiment, before the interrupt of the first timer interrupt process (FIG. 133) is permitted in step SJ705, “1” is set in the startup flag in the work area 221 for specific control in step SJ703. The external information setting process (FIG. 301) is set and the external information setting process is not executed. Then, before the start-up processing flag is cleared to "0" in step SJ721, the base value initial output processing is executed in step SJ720. Therefore, the external information setting process (FIG. 301) is not executed before the base value initial output process. As a result, the process of steps SJ605 to SJ607 of the external information setting process (FIG. 301) is executed before the base value initial output process is executed, and "1" is set to the base value abnormality flag 565. And the external output processing of the base value abnormal signal (step SJ611) is executed before the base value initial output processing is executed, and the base value abnormal signal is externally output to the abnormality annunciator EI. It is prevented from falling.

Next, the base value initial output process executed by the main CPU 63 will be described with reference to the flowchart in FIG. 303. The base value initial output process is executed in step SJ720 of the main process (FIG. 302). Further, the processing of steps SJ801 to SJ812 in the base value initial output processing is executed by using the specific control program and the specific control data in the main CPU 63.

In the base value initial output process, first, it is determined whether or not "1" is set in the base value abnormality flag 565 in the work area 221 for specific control (step SJ801). Similar to the fifteenth embodiment, backup power is supplied to the main RAM 65 provided with the work area 221 for specific control even after the pachinko machine 10 is powered off. Therefore, the numerical information of "1" set in the base value abnormality flag 565 in the specific control work area 221 is stored and retained while the backup power is supplied even after the pachinko machine 10 is powered off. .. When the reset button 68c is not pressed to restart the supply of operating power to the pachinko machine 10, the RAM clear process (step SJ716 of the main process (FIG. 302)) is not executed, and therefore the base value abnormality flag 565 is used. The base value initial output process (FIG. 303) is executed with the state "1" set to "1", and an affirmative determination is made in step SJ801. On the other hand, when the reset button 68c is pressed to restart the supply of operating power to the pachinko machine 10, the RAM clearing process is executed in step SJ716 of the main process (FIG. 302), and the base value abnormality flag 565 is executed. Is cleared to "0". In this case, a negative determination is made in step SJ801.

When it is determined in step SJ801 that "1" is not set in the base value abnormality flag 565, the threshold value table 566 is read from the main ROM 64 (step SJ802), and the calculation initial in the work area 223 for non-specific control is set. It is determined whether "1" is set in the flag (step SJ803). As already described, the calculation initial flag is the total of the game balls discharged from the game area PA in a situation in which the base value calculation period is newly started and neither the open/close execution mode due to the jackpot result nor the high frequency support mode is present. This is a flag for the main CPU 63 to specify whether or not the number (that is, the total number of game balls supplied to the game area PA) has reached the initial reference number (specifically, 6000).

When "1" is not set in the calculation initial flag (step SJ803: NO), the current area 311 (FIG. 126) in the calculation result storage area 234 is set as the reference target area (step SJ804). On the other hand, when the operation initial flag is set to “1” (step SJ803: YES), the number of samples for calculating the latest base value stored in the current area 311 is not sufficient. Therefore, the first history area 312 (FIG. 126) in the calculation result storage area 234 is set as the reference target area (step SJ805).

After that, it is determined whether or not the base value in the current reference target area exceeds the upper threshold value (0.40) set in the threshold value table 566 read in step SJ802 (step SJ806). When a negative determination is made in step SJ806, it is determined whether or not the base value in the current reference target area is lower than the lower threshold value (0.35) set in the threshold value table 566 read in step SJ802. It is determined (step SJ807).

If a negative determination is made in step SJ807, it means that the base value in the current reference target area is within the normal base range (0.35 to 0.40). It is determined whether or not it is the third history area 314 (FIG. 126) (step SJ808). If the current reference target area is not the third history area 314 (step SJ808: NO), the reference target area in the calculation result storage area 234 (FIG. 126) is updated (step SJ809) and the process returns to step SJ806. In step SJ809, the reference target area in the calculation result storage area 234 is updated in the order of the current area 311, the first history area 312, the second history area 313, and the third history area 314.

The processing of steps SJ806 to SJ809 is repeatedly executed until an affirmative determination is made in any of steps SJ806 to SJ808, and if an affirmative determination is made in step SJ806 or step SJ807, the base value abnormality signal in step SJ810 The external output processing of is executed. Therefore, the most recent base value stored in the current state area 311, the final base value in the previous calculation period stored in the first history area 312, and the second base value stored in the second history area 313. At least one of the final base value in the previous calculation period and the final base value stored in the third history area 314 in the third previous calculation period is the base normal range (0.35 to 0.40). (Step SJ806: YES or step SJ807: YES), the external output processing of the base value abnormality signal in step SJ810 is executed.

When an affirmative judgment is made in step SJ801, an affirmative judgment is made in step SJ806, or an affirmative judgment is made in step SJ807, external output processing of the base value abnormality signal is executed (step SJ810). ). In step SJ810, the same process as the external output process of the base value abnormality signal (step SJ611) in the external information setting process (FIG. 301) described above is executed. Specifically, the signal output from the main output terminal TA3 to the data signal line LN5 is output in the situation where a pulsed clock signal is output from the main output terminal TA3 of the MPU 62 to the clock signal line LN6. After rising from LOW to HI, the signal is lowered from HI to LOW. As a result, the base value abnormality signal is externally output to the abnormality alarm EI via the external terminal board 97.

As described above, the abnormality alarm EI notifies the base value abnormality based on the reception of the base value abnormality signal from the pachinko machine 10. Further, the abnormality notification device EI outputs information including the base value abnormality signal received from the pachinko machine 10 and the identifier data of the abnormality notification device EI to the hall computer HC. Therefore, the manager of the game hall immediately after starting the supply of the operating power to the pachinko machine 10, whichever of the latest base value and the past three base values of the pachinko machine 10 in the hall computer HC and the abnormality alarm EI. It is possible to understand that the base value is abnormal. For example, immediately after the supply of the operating power is started, the abnormality alarm EI notifies the base value of the pachinko machine 10 for which the abnormality of the base value has not been detected so far. It is possible to understand that the abnormalities were overlooked.

After the external output processing of the base value abnormality signal is executed in step SJ810, the base value abnormality flag 565 is cleared to "0" (step SJ811). After the base value initial output process (FIG. 303) is completed, in the external information setting process (FIG. 301), the latest base value stored in the current area 311 is the base normal range (0.35 to 0.40). ), the base value abnormality flag 565 is set to "1" (processing of step SJ607), while the first to third history areas 312 to 314 are stored. The processing for setting "1" to the base value abnormality flag 565 is not executed based on the fact that the past base value is out of the normal base range (0.35 to 0.40). By clearing the base value abnormality flag 565 to "0" in step SJ811, the external output of the base value abnormality signal based on the past base value being out of the normal base range (0.35 to 0.40) is performed. It will not be executed. When the hall computer HC and the abnormality alarm EI receive the base value abnormality signal at a timing other than immediately after the supply of the operating power to the pachinko machine 10 is started, the manager of the game hall stores the current value in the current area 311. It can be understood that the most recent base value is outside the normal range (0.35 to 0.40).

If an affirmative judgment is made in step SJ808 or the processing of step SJ811 is carried out, numerical information corresponding to 1 hour is set in the base value timer counter in the work area 221 for specific control (step SJ812), and the process for initial output of the base value ends. By setting numerical information corresponding to one hour in the base value timer counter, an output trigger of the base value abnormality signal is generated approximately one hour after the supply of operating power to the main CPU 63 is started. You can

As described above, in the base value initial output process (FIG. 303) that is executed immediately after the supply of the operating power to the main CPU 63 is started, the base value calculation period is newly started and then the jackpot result is calculated. The total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) in a situation that is neither the open/close execution mode nor the high frequency support mode is the initial reference number (specifically, 6000), the latest base value stored in the current area 311 is out of the normal base range (0.35 to 0.40), and the first to third history areas 312 to 312. When any of the past three base values stored in 314 is out of the normal base range (0.35 to 0.40), the abnormal base value signal is externally output to the abnormality alarm EI.

The action of changing the state of the nail 24b scolded on the game board 24 to a state that is disadvantageous to the player is performed, and the final base value in one calculation period is the base normal range (0.35 to 0.40). ) Lower threshold value (0.35), even if an action of returning the state of the nail 24b to a normal state is performed thereafter, the base value in the calculation period is from 1st to 1st. It remains in the third history areas 312-314. In addition, the base value is illegally increased, and the final base value in one calculation period exceeds the upper threshold value (0.40) of the normal base range (0.35 to 0.40). In such a case, even if an attempt is made to erase the trace of the illegal act thereafter, the base value in the calculation period remains in the first to third history areas 312 to 314. While the final base value in the calculation period in which these illegal acts are performed remains in any of the first to third history areas 312 to 314, supply of operating power to the pachinko machine 10 is started. The abnormality notification EI corresponding to the pachinko machine 10 can notify the abnormality of the base value every time, and the hall computer HC can grasp the abnormality of the base value of the pachinko machine 10. As a result, it is possible to reduce the possibility that the abnormality of the base value may be overlooked before the supply of the operating power to the main CPU 63 is stopped.

A part of the administrator of the game hall is involved in an illegal act of changing the state of the nail 24b to a state unfavorable to the player, or an act of illegally increasing the base value, and the administrator concerned is the base of the pachinko machine 10. In the case of being in charge of monitoring the presence/absence of a value abnormality, in the configuration in which only the base value abnormality signal based on the most recent base value in the current area 311 is externally output, the base value abnormality in the pachinko machine 10 is The administrator may not understand. On the other hand, the base value abnormality signal based on the past base values in the first to third history areas 312 to 314 is also externally output, so that the abnormality of the base value in the pachinko machine 10 is detected in a plurality of game halls. It is possible to increase the possibility that the administrator of the.

Next, how the base value abnormality signal is externally output to the abnormality alarm EI based on the abnormality of the base value in the current area 311 will be described with reference to the time chart of FIG. 304. 304(a) shows the timing at which the base value abnormality signal is externally output to the abnormality annunciator EI, FIG. 304(b) shows the state of the base value abnormality flag 565, and FIG. 304(c) shows the base value abnormality signal. 304(d) shows the timing when the output trigger occurs, and FIG. 304(d) is discharged from the game area PA in a situation where neither the opening/closing execution mode nor the high-frequency support mode depending on the jackpot result have occurred since the base value calculation period was newly started. 304(e) shows a period in which the total number of played game balls (that is, the total number of game balls supplied to the game area PA) has reached the initial reference number (specifically 6000), and FIG. 304(e) is a base value. The total number of game balls discharged from the game area PA (that is, the game balls supplied to the game area PA in a situation where neither the open/close execution mode due to the jackpot result nor the high-frequency support mode has been calculated since the calculation period was newly started. 304(g) shows the timing at which the supply of the operating power to the main CPU 63 is started, and FIG. 304(g) shows the timing when the shift reference number (specifically, 60000) is reached. Indicates the timing at which the supply of operating power to the main CPU 63 is stopped.

As shown in FIG. 304(d) at the timing of t1, since the base value calculation period is newly started, the game discharged from the game area PA in a situation where neither the open/close execution mode by the jackpot result nor the high frequency support mode is present. The total number of balls (that is, the total number of game balls supplied to the game area PA) reaches the initial reference number (specifically, 6000). After that, when the base value in the current area 311 (FIG. 126) deviates from the normal base range (0.35 to 0.40) at the timing of t2, the base value abnormality flag 565 is set to “1” as shown in FIG. 304(b). Is set.

Then, when the base value abnormality signal is output at the timing of t3 as shown in FIG. 304(c) in the situation where "1" is set in the base value abnormality flag 565, as shown in FIG. 304(a). The base value abnormality signal is externally output to the abnormality alarm EI. As a result, the hall computer HC and the abnormality annunciator EI can recognize that the abnormality of the base value has occurred in the pachinko machine 10. Further, as shown in FIG. 304(b), the base value abnormality flag 565 is cleared to "0" at the timing of t3.

Next, in a state where the base value abnormality flag 565 is set to "1", the game is performed in a situation where the base value calculation period is newly started and the open/close execution mode by the jackpot result or the high-frequency support mode is not either. A case where the total number of game balls discharged from the area PA (that is, the total number of game balls supplied to the game area PA) reaches the shift reference number (specifically, 60000) will be described.

As shown in FIG. 304(e), at the timing of t4 when the base value abnormality flag 565 is set to “1”, the opening/closing execution mode and the high frequency support mode based on the jackpot result are newly started after the base value calculation period is newly started. When the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) reaches the shift reference number (specifically, 60000) in a situation that is neither of the above, data The shift process (step S8607 of the result calculation process (FIG. 130)) is executed. In the data shift process, the information stored in the current state area 311, the first history area 312, the second history area 313, and the third history area 314 in the calculation result storage area 234 is the same as in the 35th embodiment. After shifting in the order of the second history area 313→the third history area 314, the first history area 312→the second history area 313, the current area 311→the first history area 312, the current area 311 is cleared to “0”. As a result, as shown in FIG. 304(d), the game discharged from the game area PA in a situation where the base value calculation period is newly started and the opening/closing execution mode or the high-frequency support mode according to the jackpot result is neither The total number of balls (that is, the total number of game balls supplied to the game area PA) does not reach the initial reference number (specifically, 6000). As shown in FIG. 304(b), "1" remains set in the base value abnormality flag 565 at the timing of t4.

After that, when the base value abnormality signal is output as shown in FIG. 304(c) at the timing of t5 when the base value abnormality flag 565 is set to "1", the base value abnormality signal is output as shown in FIG. 304(a). A value abnormality signal is externally output to the abnormality indicator EI. This allows the hall computer HC and the abnormality alarm EI to know that the base value of the pachinko machine 10 is out of the normal base range (0.35 to 0.40). Further, as shown in FIG. 304(b), the base value abnormality flag 565 is cleared to "0" at the timing of t5.

In this way, after the base value abnormality flag 565 is set to "1", the data shift processing is executed before the base value abnormality signal is externally output to the abnormality alarm EI, and the current area 311 is cleared to "0". If the base value abnormality signal is output, the base value abnormality signal is transmitted to the abnormality alarm device EI based on the fact that the base value abnormality flag 565 is set to "1". External output is performed. As a result, it is possible to detect in the hall computer HC and the abnormality notification device EI that the abnormality of the base value has occurred before the execution of the data shift process.

Next, with the base value abnormality flag 565 set to "1", the supply of operating power to the main CPU 63 is stopped, and thereafter the operation to the main CPU 63 is performed without pressing the reset button 68c. A case where power supply is started will be described.

At time t6 when the base value abnormality flag 565 is set to "1", the supply of operating power to the main CPU 63 is stopped as shown in FIG. 304(g). After that, at the timing of t7, as shown in FIG. 304(f), supply of operating power to the main CPU 63 is started without pressing the reset button 68c. In this case, since the RAM clearing process (step SJ716 of the main process (FIG. 302)) is not executed, the base value abnormality flag 565 is not cleared to “0” as shown in FIG. 304(b).

Thereafter, when the base value initial output process (step SJ720 of the main process (FIG. 302)) is executed at the timing of t8, based on the fact that the base value abnormality flag 565 is set to “1”, External signal external output processing (step SJ810) is executed. As a result, the base value abnormality signal is externally output to the abnormality alarm EI as shown in FIG. 304(a). Further, at the timing of t8, the base value abnormality flag 565 is cleared to "0" as shown in FIG. 304(b).

In this way, the supply of operating power to the main CPU 63 is stopped with the base value abnormality flag 565 set to "1", and thereafter the main CPU 63 is supplied to the main CPU 63 without pressing the reset button 68c. When the supply of the operating power is started, based on the fact that the base value abnormality flag 565 is set to "1", the external output of the base value abnormality signal to the abnormality alarm device EI is started at the start of the supply of the operating power. Done. As a result, it is possible for the hall computer HC and the abnormality alarm EI to recognize that the abnormality of the base value has occurred when the supply of the operating power to the main CPU 63 is stopped.

Next, with reference to the time chart of FIG. 305, the manner in which the base value abnormality signal is externally output to the abnormality alarm EI based on the abnormality of the base value in the first history area 312 to the third history area 314 will be described. 305(a) shows the timing at which the base value abnormality signal is externally output to the abnormality alarm device EI, FIG. 305(b) shows the state of the base value abnormality flag 565, and FIG. 305(c) shows the calculation of the base value. The total number of game balls discharged from the game area PA in a situation where neither the open/close execution mode due to the jackpot result nor the high frequency support mode has been started since the period was newly started (that is, the total number of game balls supplied to the game area PA. 305 (d) shows the period during which the initial reference number (specifically 6000) has been reached, and FIG. 305 (d) shows the switching execution mode and high-frequency support based on the jackpot result since the base value calculation period was newly started. Timing when the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) reaches the shift reference number (specifically, 60000) in a situation that is neither of the modes. 305(e) shows the timing at which the supply of operating power to the main CPU 63 is started, and FIG. 305(f) shows the timing at which the supply of operating power to the main CPU 63 is stopped.

As shown in FIG. 305(c), at the timing of t1, the base value calculation period is newly started and then discharged from the game area PA in a situation where neither the open/close execution mode by the jackpot result nor the high frequency support mode is present. The total number of game balls (that is, the total number of game balls supplied to the game area PA) has reached the initial reference number (specifically, 6000). When the latest base value stored in the current area 311 deviates from the normal base range (0.35 to 0.40) at the timing of t1, the base value abnormality flag 565 indicates “abnormal” as shown in FIG. 305(b). 1” is set.

After that, at the timing of t2 before the output trigger of the base value abnormality signal is generated, as shown in FIG. 305(d), the base value calculation period is newly started and the opening/closing execution mode depending on the jackpot result and The total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) in a situation in which neither of the high frequency support modes is the shift reference number (specifically, 60000) When it reaches, the data shift process (step S8607 of the result calculation process (FIG. 130)) is executed. In the data shift process, the information stored in the current state area 311, the first history area 312, the second history area 313, and the third history area 314 in the calculation result storage area 234 is the same as in the 35th embodiment. After shifting in the order of the second history area 313→the third history area 314, the first history area 312→the second history area 313, the current area 311→the first history area 312, the current area 311 is cleared to “0”. As a result, the base value stored in the first history area 312 is out of the normal base range (0.35 to 0.40). Also, as shown in FIG. 305(c), a game ball discharged from the game area PA in a situation where the base value calculation period is newly started and the open/close execution mode or the high frequency support mode depending on the jackpot result is neither The total number (that is, the total number of game balls supplied to the game area PA) does not reach the initial reference number (specifically, 6000). As shown in FIG. 305(b), the base value abnormality flag 565 remains set to "1" at the timing of t2.

Thereafter, at the timing of t3, the supply of the operating power to the main CPU 63 is stopped as shown in FIG. 305(f). Then, at timing t4, as shown in FIG. 305(e), while the reset button 68c is being pressed, the supply of operating power to the main CPU 63 is restarted. In this case, since the RAM clearing process (step SJ716 of the main process (FIG. 302)) is executed, the base value abnormality flag 565 is cleared to “0” as shown in FIG. 305(b) at the timing of t4. .. In this case, the base value abnormality flag 565 is set to "1" based on the fact that the latest base value in the current area 311 is out of the normal base range (0.35 to 0.40). When the base value abnormality flag 565 is set to "1", the base value abnormality flag 565 is cleared to "0" without the base value abnormality signal being externally output to the abnormality indicator EI. I will end up. Further, the base value stored in the current area 311 is shifted to the first history area 312 by the data shift process executed at the timing of t2. Therefore, no abnormal base value remains in the current area 311 and even if the external information setting process (FIG. 301) is executed after the timing of t4, the external output of the base value abnormality signal based on the base value is performed. Is not done. In the present embodiment, the base value initial output process (FIG. 303) executes the external output of the base value error signal based on the past base value, so that the base value error signal is not output externally and the first history is output. It is possible to understand that there is an abnormal base value (base value outside the normal base range) shifted to the area 312.

After that, when the base value initial output process (step SJ720 of the main process (FIG. 302)) is started at the timing of t5, the base stored in the first history area 312 (FIG. 126) of the calculation result storage area 234 is started. Based on the value being out of the normal base range (0.35 to 0.40), "1" is set to the base value abnormality flag 565 as shown in FIG. 305(b). In the base value initial output process, the external output process of the base value abnormal signal (step SJ810) is executed based on the base value abnormal flag 565 being set to "1". As a result, the base value abnormality signal is externally output to the abnormality alarm EI as shown in FIG. 305(a) at the timing of t6. Further, at the timing of t6, as shown in FIG. 305(b), the base value abnormality flag 565 is cleared to "0".

Thus, even if the latest base value stored in the current area 311 is out of the normal base range (0.35 to 0.40), the base value is still in the normal base range (0.35 to 0.40). It is possible that the base value abnormality signal is not externally output based on the deviation from 0.40). In the configuration in which the base value abnormal signal is externally output only when the base value in the current area 311 is out of the normal base range (0.35 to 0.40), the base value is in the normal base range (0.35 to 0.40). There is a possibility that it may be overlooked that the state that is out of the range has occurred. On the other hand, in the present embodiment, the base values in the first to third history areas 312 to 314 deviate from the normal base range (0.35 to 0.40) at the start of supplying the operating power to the main CPU 63. Even if it is present, the base value abnormality signal is output externally. This prevents the occurrence of a state in which the base value is out of the normal base range (0.35 to 0.40) from being overlooked.

Further, in the base value initial output process (FIG. 303) performed immediately after the supply of the operating power to the main CPU 63 is started, the data shift process is executed and an abnormal base value outside the normal base range is detected. Even if the external output of the base value abnormality signal based on the abnormal base value is executed before shifting from the current state area 311 to the first history area 312, the abnormal state stored in the first history area 312 is detected. External output of the base value abnormality signal based on the base value is performed again. This reduces the possibility that an abnormality in the base value will be overlooked. Further, it is possible to increase the possibility that a plurality of managers in the game hall will grasp the abnormality of the base value.

According to this embodiment described in detail above, the following excellent effects are exhibited.

Based on the threshold value table 566 previously stored in the main ROM 64, it is determined whether or not the base value is within the normal base range (0.35 to 0.40). Then, only when it is determined that the base value is out of the normal base range, the base value abnormality signal is externally output to the abnormality alarm EI. Therefore, even when the pachinko machine 10 is connected to the general-purpose abnormality alarm EI used for a plurality of models having different base normal ranges, the base value of the pachinko machine 10 falls within the base normal range. It is possible to easily determine whether or not there is an abnormality in the abnormality indicator EI. Further, also in the hall computer HC connected to the abnormality notification device EI corresponding to a plurality of models having different base normal ranges, the pachinko machine 10 based on the base value abnormality signal received from the abnormality notification device EI corresponding to the pachinko machine 10. It is possible to easily determine whether or not the base value of is within the normal range of the base.

Since the base value abnormality signal is externally output to the abnormality annunciator EI, the abnormality of the base value can be grasped by comparison with the configuration in which the numerical information indicating the base value is externally output to the abnormality annunciator EI. The amount of data to be output to the outside is reduced. As a result, the base value abnormality signal is externally output also to the abnormality indicator EI and the hall computer HC in which the storage capacity of the storage area for receiving and storing the data allowing the abnormality of the base value to be grasped is set small. It is possible.

Since the base value calculation period was newly started, the total number of game balls discharged from the game area PA (that is, supplied to the game area PA in a situation where neither the open/close execution mode due to the jackpot result nor the high-frequency support mode is used). When the total number of game balls has not reached the initial reference number (specifically 6000), it is determined whether the base value is within the base normal range (0.35 to 0.40). Not done Since the external output of the base value abnormality signal is not executed in the state where the game history information for calculating the base value is insufficient, the hall computer HC and the abnormality alarm EI are based on an unstable base value. Reception of an abnormal signal is prevented. This prevents frequent maintenance of adjusting the state of the nails 24b scrambled on the game board 24 and confirmation of the presence or absence of an action that illegally raises the total payout number of game balls. Therefore, the reliability of the abnormal base value signal is improved.

At the timing when the supply of operating power to the main CPU 63 is started, one of the past base values stored in the first history area 312 to the third history area 314 is in the base normal range (0.35 to 0.40). ), the base value abnormality signal is externally output to the abnormality alarm device EI when the supply of the operating power is started. As a result, when the abnormal base value outside the normal base range is stored in the current area 311 and the base value abnormality signal based on the abnormal base value is not externally output, It is possible to grasp that the abnormality of the base value is generated by the external output of the base value abnormality signal based on the abnormal base value stored in any of the third history areas 312 to 314.

After the abnormal base value outside the normal base range is stored in the current area 311 and the base value abnormal signal is output to the outside, the abnormal base value is first to second. When the shift is made to the third history areas 312 to 314, the base value initial output process (FIG. 303) is executed at the start of the supply of the operating power to the pachinko machine 10, and the base value abnormality signal based on the abnormal base value is output. External output is executed again. As a result, it is possible to prevent the abnormality of the base value from being overlooked, and it is possible to increase the possibility that a plurality of managers in the game hall will grasp the abnormality of the base value. When a plurality of managers of the game hall grasp the abnormality of the base value, a part of the manager of the game hall changes the state of the nail 24b into a state that is disadvantageous to the player, or the base value is illegal. Even if the administrator is involved in the act of increasing the value of the pachinko machine 10 and is in charge of monitoring the presence or absence of an abnormality in the base value of the pachinko machine 10, another administrator discovers these illegal acts. Can be enabled.

Ejection from the game area PA in a situation where the base value calculation period is newly started while the base value abnormality flag 565 is set to "1" and the open/close execution mode by the jackpot result and the high frequency support mode are neither The total number of played game balls (that is, the total number of game balls supplied to the game area PA) reaches the shift reference number (specifically, 60000) and the current area 311 is cleared to “0”, and then the main Even if the supply of the operating power to the side CPU 63 is stopped, the base value abnormality signal is externally output to the abnormality alarm EI at the timing when the supply of the operating power to the main CPU 63 is restarted. This reduces the possibility that the base value abnormality of the pachinko machine 10 is overlooked.

A configuration in which the output trigger of the base value abnormality signal is generated at a predetermined time interval (specifically, one hour interval) and the base value abnormality signal is externally output under the condition of the generation trigger of the base value abnormality signal as one condition. As a result, the number of times the base value abnormality signal external output process (step SJ611) is executed in the external information setting process (FIG. 301) is reduced. When the base value in the current area 311 is out of the normal base range (0.35 to 0.40), the base value abnormality signal is output externally every predetermined time (specifically, every one hour). Can be output. As a result, it is possible to output the base value abnormality signal to a plurality of times while preventing the external output of the base value abnormality signal from being continuously executed in a short period of time.

When the base value exceeds the upper threshold value (0.40) of the normal base range (0.35 to 0.40), or when the base value falls below the lower threshold value (0 to 0) of the normal base range (0.35 to 0.40). .35), the process of setting "1" to the base value abnormality flag 565 (the process of steps SJ603 to SJ607 in the external information setting process (FIG. 301)) is the game stop flag and the in-process flag. Is performed every time the first timer interrupt process (FIG. 133) is executed in a situation where "1" is not set. Due to the configuration in which these processes are executed in a relatively short cycle (specifically, 4 ms cycle), the base value is temporarily out of the normal base range (0.35 to 0.40). Therefore, even when the normal value range (0.35 to 0.40) is restored before the output trigger of the base value abnormality signal occurs, the base value abnormality signal can be externally output to the abnormality alarm EI. As a result, in a configuration in which the output trigger of the base value abnormality signal is generated at a predetermined time interval (specifically, one hour interval), the base value abnormality signal is received based on the base value abnormality signal received by the hall computer HC and the abnormality alarm device EI. It is possible to grasp a temporary abnormality in the value.

In the external information setting process (FIG. 301), a process of determining whether or not the base value is above the upper threshold value (0.40) of the normal base range (0.35 to 0.40) (process of step SJ605). ), and the process of determining whether or not the base value is below the lower threshold value (0.35) (the process of step SJ606) may be executed only at the timing of the output trigger of the base value abnormality signal. .. With this configuration, when the base value exceeds the upper threshold value (0.40) of the normal base range (0.35 to 0.40) at the timing when the value of the base value timer counter becomes “0”, and When the value is below the lower threshold value (0.35), the base value abnormality signal can be externally output to the abnormality indicator EI. In this configuration, when the base value in the current area 311 temporarily deviates from the base normal range (0.30 to 0.40) and returns to the base normal range before the output trigger of the base value abnormal signal occurs, the base value The abnormal signal is not output externally. With this configuration, the base value abnormality signal can be output to the outside only when the base value in the current area 311 is out of the normal base range, and the manager of the game hall can be prompted to take action. Further, with this configuration, the configuration for executing the external output of the base value abnormality signal by omitting the base value abnormality flag 565 can be simplified.

Further, instead of the configuration in which the base value abnormality signal is externally output based on the latest base value and the past base value at the time of starting the supply of the operating power to the main CPU 63, at the time of starting the supply of the operating power to the main CPU 63. The base value abnormality signal may be externally output based on only the past base value. Specifically, in the base value initial output process (FIG. 303), the base value abnormality flag 565 is first cleared to "0". As a result, when the information “1” set in the base value abnormality flag 565 is stored and held before the supply of the operating power to the main CPU 63 is stopped, the state of the base value abnormality flag 565 is set. It is avoided that the base value abnormality signal is externally output based on the above. In the base value initial output process (FIG. 303 ), the processes of steps SJ806 to 807 are executed using the first to third history areas 312 to 314 as reference target areas, while the current area 311 is not set as a reference target area. .. Accordingly, when any of the past three base values stored in the first to third history areas 312 to 314 is out of the normal base range (0.35 to 0.40), the base value abnormality signal is output. While the abnormality indicator EI is externally output, the base value abnormality signal indicates that the latest base value stored in the current area 311 is out of the normal base range (0.35 to 0.40). Is not output externally. In this configuration, when the hall computer HC and the abnormality alarm EI receive the base value abnormality signal immediately after the supply of the operating power to the pachinko machine 10 is started, the administrator of the gaming hall determines that the base normal range (0.35 It can be understood that the base value deviating from (.about.0.40) is any of the past base values stored in the first to third history areas 312 to 314.

<85th Embodiment>
This embodiment is different from the 84th embodiment in that two types of base value abnormality signals are externally output. The configuration different from that of the 84th embodiment will be described below. The description of the same configuration as the 84th embodiment is basically omitted.

Similar to the 84th embodiment, the numerical range of "0.35" to "0.40" is set as the base normal range, and "0.40" is set as the upper threshold of the base normal range. In addition, “0.35” is set as the lower threshold value of the normal base range. In the present embodiment, when the base value exceeds the upper threshold value (0.40) of the normal base range, the upper base value abnormality signal is externally output to the abnormality alarm EI, and the base value is lower than the normal base range. When the value is below the threshold value (0.35), the lower base value abnormality signal is externally output to the abnormality alarm EI.

FIG. 306(a) is a block diagram for explaining a configuration for externally outputting the upper base value abnormality signal and the lower base value abnormality signal in the present embodiment. As shown in FIG. 306(a), the MPU 62 is provided with a main output terminal TA4 for outputting an upper base value abnormality signal from the main CPU 63, and the external terminal board 97 has the main output terminal TA4. An external receiving terminal TB4 for receiving the upper base value abnormality signal output from TA4 is provided. The main output terminal TA4 and the external reception terminal TB4 are electrically connected to each other by using the upper data signal line LN7 and the upper clock signal line LN8. All of these signal lines LN7 to LN8 are signal lines for transmitting signals from the main CPU 63 to the external terminal board 97 by one-way communication.

An upper base value abnormality signal is transmitted by serial communication from the main CPU 63 to the external terminal board 97 using the upper data signal line LN7. In this case, each 1-bit division of the upper base value abnormality signal by serial communication is indicated by a clock signal transmitted from the main CPU 63 to the external terminal board 97 using the upper clock signal line LN8.

As shown in FIG. 306(a), the MPU 62 is provided with a main output terminal TA5 for outputting a lower base value abnormality signal from the main CPU 63, and the external terminal board 97 is provided with the main output. An external receiving terminal TB5 for receiving a lower base value abnormality signal output from the terminal TA5 is provided. The main output terminal TA5 and the external reception terminal TB5 are electrically connected to each other by using the lower data signal line LN9 and the lower clock signal line LN10. All of these signal lines LN9 to LN10 are signal lines for transmitting signals from the main CPU 63 to the external terminal board 97 by one-way communication.

A lower base value abnormality signal is transmitted from the main CPU 63 to the external terminal board 97 by serial communication using the lower data signal line LN9. In this case, each 1-bit division of the lower base value abnormality signal by serial communication is indicated by the clock signal transmitted from the main CPU 63 to the external terminal board 97 using the lower clock signal line LN10.

The external terminal board 97 includes an external output terminal TC4 for externally outputting the upper base value abnormality signal received by the external reception terminal TB4 and a lower base value abnormality signal received by the external reception terminal TB5. An external output terminal TC5 for external output is provided. These external output terminals TC4, TC5 can be connected to an external device such as an abnormality alarm EI provided outside the pachinko machine 10. The abnormality alarm device EI is provided in one-to-one correspondence with the pachinko machine 10. The abnormality alarm device EI includes a light emitting unit. The abnormality annunciator EI notifies the abnormality that the base value exceeds the upper threshold value (0.40) of the normal base range (0.35 to 0.40) when the upper base value abnormality signal is received from the pachinko machine 10. In the light emission mode for performing the above, the light emitting unit emits light to notify the upper side abnormality of the base value, and when the lower side base value abnormality signal is received from the pachinko machine 10, the base value is within the base normal range (0.35 to 0). .40) lower than the lower threshold value (0.35), the light emitting unit is caused to emit light in a light emitting mode for notifying an abnormality, and the lower abnormality notification of the base value is performed. Specifically, the light emitting unit emits yellow light when the upper abnormality is notified, and the light emitting unit emits red light when the lower abnormality is notified. The manager of the game hall can grasp the presence/absence of the abnormality of the base value in the pachinko machine 10 and the type of abnormality based on the upper abnormality notification and the lower abnormality non-notification in the abnormality alarm EI.

The hall computer HC is electrically connected to an abnormality alarm device EI provided in a one-to-one correspondence with a large number of pachinko machines installed in the game hall. The abnormality notification device EI outputs information including the base value abnormality signal received from the pachinko machine 10 and the identifier data of the abnormality notification device EI to the hall computer HC. The base value abnormality signal is output from the abnormality alarm device EI to the hall computer HC in such a manner that the upper base value abnormality signal and the lower base value abnormality signal can be distinguished. The hall computer HC identifies the pachinko machine 10 based on the identifier data received from the abnormality annunciator EI and, based on the base value abnormality signal received at the same time as the identifier data, detects the abnormality of the base value in the pachinko machine 10. Understand the existence and types of abnormalities. The manager of the game hall can also grasp the presence/absence of an abnormality in the base value of the pachinko machine 10 and the type of abnormality also in the hall computer HC.

By making it possible to grasp that the hall computer HC and the abnormality alarm EI are in an abnormal state in which the base value exceeds the upper threshold value (0.40) of the base normal range (0.35 to 0.40), it is possible to play the game. It is possible to give the manager of the hall an opportunity to confirm whether or not there is an action that illegally raises the total payout number of gaming balls. Further, it is possible to grasp that the hall computer HC and the abnormality alarm EI are in an abnormal state in which the base value is below the lower threshold value (0.35) of the base normal range (0.35 to 0.40). As a result, the manager of the game hall can be given an opportunity for maintenance to adjust the state of the nails 24b scolded on the game board 24 of the pachinko machine 10 and the like.

It is easy to be in an abnormal state in which the base value exceeds the upper threshold value (0.40) of the base normal range (0.35 to 0.40) because the upper value abnormality notification of the base value is performed in the abnormality alarm device EI. In addition, it is possible to grasp the lower limit value (0) of the base value in the normal range of base (0.35 to 0.40) by performing the lower abnormality notification of the base value in the abnormality alarm EI. .35), it is possible to easily understand that the condition is abnormal.

FIG. 306(b) is an explanatory diagram for explaining a storage area for external output of the upper base value abnormality signal and the lower base value abnormality signal provided in the work area 221 for specific control. As shown in FIG. 306(b), an upper base value abnormality flag 567 and a lower base value abnormality flag 568 are provided in the work area 221 for specific control. The upper base value abnormality flag 567 is a flag that enables the main CPU 63 to know that an abnormal state in which the base value exceeds the upper threshold value (0.40) of the base normal range (0.35 to 0.40) has occurred. In addition, the lower base value abnormality flag 568 informs the main CPU 63 that an abnormal state in which the base value falls below the lower threshold value (0.35) of the base normal range (0.30 to 0.40) has occurred. It is a flag that can be grasped.

In the main CPU 63, similarly to the 84th embodiment, when the operating power supply to the main CPU 63 is started, it is stored in the first history area 312 to the third history area 314 (FIG. 126) in the calculation result storage area 234. It is determined whether or not the current base value is within the normal base range (0.35 to 0.40). Further, similarly to the 84th embodiment, after the supply of the operating power to the main CPU 63 is started, whether the base value in the current area 311 (FIG. 126) in the calculation result storage area 234 is within the normal base range or not. Is determined. In these determinations, when the base value is above the upper threshold value (0.40), the upper base value abnormality flag 567 is set to "1" and the base value is below the lower threshold value (0.35). If it is, the lower base value abnormality flag 568 is set to “1”.

Similar to the 84th embodiment, the output trigger of the base value abnormality signal is generated every predetermined time (specifically, 1 hour) after the supply of the operating power to the main CPU 63 is started. In a state where the upper base value abnormality flag 567 is set to "1", the upper base value abnormality signal is externally output to the abnormality alarm device EI on the basis of the occurrence of the output of the base value abnormality signal. In addition, while the lower base value abnormality flag 568 is set to "1", the lower base value abnormality signal is transmitted to the abnormality alarm device EI based on the occurrence of the output trigger of the base value abnormality signal. External output is executed.

Next, a specific processing configuration for externally outputting the upper base value abnormality signal and the lower base value abnormality signal will be described. FIG. 307 is a flowchart showing the external information setting process executed by the main CPU 63. The external information setting process is executed in step S8918 of the first timer interrupt process (FIG. 133). Further, the processing of steps SJ901 to SJ908 in the external information setting processing is executed using the specific control program and the specific control data in the main CPU 63.

In the external information setting process, it is first determined whether or not "1" is set in the calculation initial flag in the work area 223 for non-specific control (step SJ901). Similar to the 35th embodiment, the calculation initial flag is discharged from the game area PA in a situation where the base value calculation period is newly started and the open/close execution mode or the high frequency support mode depending on the jackpot result is neither. A flag for the main CPU 63 to specify whether or not the total number of game balls (that is, the total number of game balls supplied to the game area PA) has reached the initial reference number (specifically, 6000). Is.

When it is determined in step SJ901 that "1" is not set in the calculation initial flag, neither the open/close execution mode depending on the jackpot result nor the high frequency support mode has been set since the base value calculation period was newly started. It means that the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) has reached the initial reference number (specifically, 6000) in the situation. In this case, the current base value is grasped by referring to the current area 311 (FIG. 126) in the calculation result storage area 234 (step SJ902).

Then, the threshold table 566 (FIG. 300(c)) is read from the main ROM 64 (step SJ903), and the abnormality flag setting process is executed based on the read threshold table 566 (step SJ904). FIG. 308 is a flow chart showing the abnormality flag setting process.

In the abnormality flag setting process, first, it is determined whether or not the upper base value abnormality flag 567 in the work area 221 for specific control is set to "1" (step SK101). As described above, the upper side base value abnormality flag 567 causes the main side CPU 63 to indicate that an abnormal state in which the base value exceeds the upper side threshold value (0.40) of the base normal range (0.35 to 0.40) has occurred. It is a flag that can be grasped. When a negative determination is made in step SK101, it is determined whether or not the base value in the current area 311 exceeds the upper threshold value (0.40) set in the threshold value table 566 (step SK102), and the base value is set. If the value exceeds the upper threshold value (step SK102: YES), the upper base value abnormality flag 567 is set to "1" (step SK103).

If an affirmative judgment is made in step SK101 or a negative judgment is made in step SK102, whether or not "1" is set to the lower base value abnormality flag 568 in the work area 221 for specific control. It is determined (step SK104). As described above, the lower base value abnormality flag 568 indicates that the main CPU 63 indicates that an abnormal state in which the base value is below the lower threshold value (0.35) of the base normal range (0.30 to 0.40) has occurred. It is a flag that can be grasped by. When a negative determination is made in step SK104, it is determined whether or not the base value in the current area 311 is below the lower threshold value (0.35) set in the threshold value table 566 (step SK105), and the base value is determined. Is below the lower threshold value (step SK105: YES), the lower base value abnormality flag 568 is set to "1" (step SK106), and this abnormality flag setting process ends.

Returning to the description of the external information setting process (FIG. 307), if an affirmative judgment is made in step SJ901 or if the abnormality flag setting process is executed in step SJ904, the process proceeds to step SJ905. In steps SJ905 to SJ906, the same processing as steps SJ608 to SJ609 in the external information setting processing (FIG. 301) of the 84th embodiment is executed. Specifically, it is determined whether or not the value of the base value timer counter provided in the specific control work area 221 has become "0" (step SJ905). Similar to the 84th embodiment, the base value timer counter is a timer counter that allows the main CPU 63 to grasp the output trigger of the base value abnormality signal. Numerical information corresponding to one hour is set in the base value timer counter in step SJ906 described later and step SK307 in the base value initial output process (FIG. 310) described later. Similar to the 84th embodiment, the value of the base value timer counter is updated by the timer update process (step S8910 of the first timer interrupt process (FIG. 133)).

When an affirmative determination is made in step SJ905, numerical information corresponding to one hour is set in the base value timer counter (step SJ906). As a result, the output trigger of the base value abnormality signal can be generated again after one hour. Then, the abnormal signal output process is executed (step SJ907). FIG. 309 is a flowchart showing the abnormal signal output processing. The abnormal signal output process is also executed in step SK306 of the base value initial output process (FIG. 310) described later.

In the abnormal signal output process, when the upper base value abnormality flag 567 in the work area 221 for specific control is set to "1" (step SK201: YES), the external base value abnormality signal external output process is executed. (Step SK202). In the external output processing of the upper base value abnormality signal, in the situation where the pulsed clock signal is output from the main output terminal TA4 of the MPU 62 to the upper clock signal line LN8, the main output terminal TA4 outputs the upper data signal line. After the signal output to LN7 is raised from LOW to HI, the signal is lowered from HI to LOW. As a result, the upper base value abnormality signal is externally output to the abnormality alarm EI via the external terminal board 97. As described above, the abnormality annunciator EI outputs the upper base value abnormality signal and the identifier data to the hall computer HC when the upper base value abnormality signal is received from the pachinko machine 10. Thereby, it is possible to grasp that the hall computer HC and the abnormality alarm EI are in an abnormal state in which the base value exceeds the upper threshold value (0.40) of the normal base range (0.35 to 0.40). You can After that, the upper base value abnormality flag 567 is cleared to "0" (step SK203).

When a negative determination is made in step SK201, or when the process of step SK203 is performed, it is determined whether or not "1" is set in the lower base value abnormality flag 568 in the work area 221 for specific control. The determination is made (step SK204). When "1" is set in the lower base value abnormality flag 568 (step SK204: YES), external output processing of the lower base value abnormality signal is executed (step SK205). In the external output processing of the lower base value abnormality signal, the main output terminal TA5 of the MPU 62 outputs a pulsed clock signal to the lower clock signal line LN10 from the main output terminal TA5 of the lower side. After the signal output to the data signal line LN9 is raised from LOW to HI, the signal is lowered from HI to LOW. As a result, the lower base value abnormality signal is externally output to the abnormality alarm EI via the external terminal board 97. As described above, when the abnormality alarm device EI receives the lower base value abnormality signal from the pachinko machine 10, the abnormality alarm device EI sends the lower base value abnormality signal and the identifier data of the abnormality alarm device EI to the hall computer HC. Output. This makes it possible to grasp that the hall computer HC and the abnormality alarm EI are in an abnormal state in which the base value is below the lower threshold value (0.35) of the base normal range (0.35 to 0.40). be able to. After that, the lower base value abnormality flag 568 is cleared to "0" (step SK206), and this abnormality signal output processing is ended.

Returning to the description of the external information setting process (FIG. 307), if a negative determination is made in step SJ905 or if the process of step SJ907 is performed, another external output process is executed (step SJ908), This external information setting process ends. The other external information output processing (step SJ908) in step SJ908 is in the open/close execution mode, similarly to the other external output processing (step SJ406) in the external information setting processing (FIG. 296) of the 82nd embodiment. Information indicating that the support mode is in the high-frequency support mode, information indicating that one game has ended, a predetermined number (for example, 100) of game balls are the outlet 24a, the general winning opening 31, information indicating that the game ball has entered the first operation port 33, information indicating that the game ball has been discharged from the game area PA through any one of the special prize winning device 32, the first operation port 33, and the second operation port 34. , And a process for externally outputting information indicating that a game ball has entered the second operating port 34 to the abnormality alarm EI.

As described above, since the base value calculation period is newly started, the total number of game balls discharged from the game area PA in a situation that is neither the open/close execution mode due to the jackpot result nor the high-frequency support mode (that is, the game area PA). When the base value in the current area 311 exceeds the upper threshold value (0.40) while the initial reference number (specifically 6000 pieces) of the game balls supplied to The base value abnormality signal is externally output, and when the base value is below the lower threshold value (0.35), the lower base value abnormality signal is externally output.

When the base value exceeds the upper threshold value (0.40), the base value abnormality signal (upper base value abnormality signal) externally output to the abnormality alarm device EI and the base value fall below the lower threshold value (0.35). In this case, the base value abnormality signal (lower side base value abnormality signal) externally output to the abnormality alarm device EI can be distinguished. Further, as described above, the abnormality notification device EI outputs information including the base value abnormality signal received from the pachinko machine 10 and the identifier data of the abnormality notification device EI to the hall computer HC. The base value abnormality signal is output from the abnormality alarm device EI to the hall computer HC in such a manner that the upper base value abnormality signal and the lower base value abnormality signal can be distinguished. Therefore, compared with the configuration in which one type of base value abnormality signal is externally output to the abnormality alarm device EI, the base value for the normal base range (0.30 to 0.40) in the hall computer HC and the abnormality alarm device EI. The state of can be grasped in detail.

Since the base value calculation period was newly started, the total number of game balls discharged from the game area PA (that is, supplied to the game area PA in a situation where neither the open/close execution mode due to the jackpot result nor the high-frequency support mode is used). If the total number of gaming balls has not reached the initial reference number (specifically 6000), the abnormality flag setting process (step SJ904) is not executed. Immediately after the start of the calculation period, since there is little information on the game history for calculating the base value, the actual measurement value of the base value may be a value that is largely outside the theoretical value range of the base value. Since the abnormality flag setting process (step SJ904) is not executed when the game history information for calculating the base value is insufficient, the hall computer HC and the abnormality alarm EI are based on the unstable base value. Reception of the upper base value abnormality signal and the lower base value abnormality signal is prevented. This prevents frequent maintenance of adjusting the state of the nails 24b scrambled on the game board 24 and confirmation of the presence or absence of an action that illegally raises the total payout number of game balls. Has been done.

Next, the base value initial output process executed by the main CPU 63 will be described with reference to the flowchart in FIG. The base value initial output process is executed in step SJ720 of the main process (FIG. 302). Further, the processes of steps SK301 to SK309 in the base value initial output process are executed by using the specific control program and the specific control data in the main CPU 63.

In steps SK301 to SK304, the same processing as steps SJ802 to SJ805 in the base value initial output processing (FIG. 303) of the 84th embodiment is performed. Specifically, first, the threshold table 566 (FIG. 300(c)) is read from the main ROM 64 (step SK301). Then, it is determined whether or not "1" is set in the calculation initial flag in the work area 223 for non-specific control (step SK302). As already described, the calculation initial flag is the total of the game balls discharged from the game area PA in a situation in which the base value calculation period is newly started and neither the open/close execution mode due to the jackpot result nor the high frequency support mode is present. This is a flag for the main CPU 63 to specify whether or not the number (that is, the total number of game balls supplied to the game area PA) has reached the initial reference number (specifically, 6000).

If "1" is not set in the calculation initial flag (step SK302: NO), the current area 311 (FIG. 126) in the calculation result storage area 234 is set as the reference target area (step SK303). On the other hand, when the operation initial flag is set to “1” (step SK302: YES), the number of samples for calculating the latest base value stored in the current area 311 is not sufficient. Therefore, the first history area 312 (FIG. 126) in the calculation result storage area 234 is set as the reference target area (step SK304).

When the process of step SK303 or the process of step SK304 is performed, the processes of steps SK305 to SK307 are executed for the current reference target area. Specifically, first, the abnormality flag setting process already described with reference to FIG. 308 is executed (step SK305). As a result, the base value in the current reference target area is set in the threshold value table 566 read in step SK301 when "1" is not set in the upper base value abnormality flag 567 in the work area 221 for specific control. If the upper threshold value (0.40) is exceeded, the upper base value abnormality flag 567 is set to "1". Further, the base value in the current reference target area is set in the threshold value table 566 read in step SK301 in the state where “1” is not set in the lower base value abnormality flag 568 in the work area 221 for specific control. If it is below the lower threshold value (0.35), the lower base value abnormality flag 568 is set to "1".

Then, it is determined whether or not the current reference target area is the third history area 314 (step SK306). If the current reference target area is not the third history area 314 (step SK306: NO), the reference target area in the calculation result storage area 234 (FIG. 126) is updated (step SK307), and the process returns to step SK305. In step SK307, the reference target area in the calculation result storage area 234 is updated in the order of the current area 311, the first history area 312, the second history area 313, and the third history area 314. As a result, in the state where the reference target area is the current state area 311, the first history area 312, the state where the reference target area is the second history area 313, and the state where the reference target area is the third history area 314, in step SK303. The abnormality flag setting process (FIG. 308) can be performed. Therefore, the final base value stored in the first history area 312 in the previous calculation period, the final base value stored in the second history area 313 in the second calculation period, and At least one of the final base values stored in the third history area 314 in the calculation period three times before is above the upper threshold value (0.40) of the normal base range (0.35 to 0.40). If (step SK102: YES), "1" is set to the upper base value abnormality flag 567 in step SK103, and at least one of these final base values is in the normal base range (0.35 to 0.40). ) Is below the lower threshold (0.35) (step SK105: YES), "1" is set to the lower base value abnormality flag 568 in step SK106.

If an affirmative decision is made in step SK306, the abnormal signal output processing already described with reference to FIG. 309 is executed (step SK308). As a result, when “1” is set in the upper base value abnormality flag 567 in the work area 221 for specific control, the external output processing of the upper base value abnormality signal is executed and the upper base value abnormality flag 567 is set. "0" is cleared. In the external output processing of the upper base value abnormality signal, the upper base value abnormality signal is externally output to the abnormality alarm EI. If "1" is set in the lower base value abnormality flag 568 in the work area 221 for specific control, the lower base value abnormality signal is externally output and the lower base value abnormality flag is output. 568 is cleared to “0”. In the external output processing of the lower base value abnormality signal, the lower base value abnormality signal is externally output to the abnormality alarm EI.

After that, numerical information corresponding to one hour is set in the base value timer counter in the work area 221 for specific control (step SK309), and this base value initial output process is terminated. By setting the numerical information corresponding to one hour in the base value timer counter, it is possible to generate an output trigger of the base value abnormality signal approximately one hour after the supply of operating power to the main CPU 63 is started. it can.

As described above, in the base value initial output process (FIG. 310) executed immediately after the supply of the operating power to the main CPU 63 is started, the latest base value and the first base value stored in the current area 311 are stored. When any of the past three base values stored in the history area 312 to the third history area 314 exceeds the upper threshold value (0.40), the upper base value abnormality signal is externally output to the abnormality alarm EI. At the same time, the lower base value abnormality signal is externally output to the abnormality alarm EI when the lower threshold value (0.35) is exceeded. This reduces the possibility that an abnormality in the base value that deviates from the normal base range (0.35 to 0.40) will be overlooked.

According to this embodiment described in detail above, the following excellent effects are exhibited.

When the base value exceeds the upper threshold value (0.40), the upper base value abnormality signal is externally output to the abnormality annunciator EI, and when the lower base threshold value (0.35) is exceeded, the lower base value abnormality occurs. The signal is externally output to the abnormality alarm device EI. The abnormality notification device EI outputs information including the base value abnormality signal received from the pachinko machine 10 and the identifier data of the abnormality notification device EI to the hall computer HC. The base value abnormality signal is output from the abnormality alarm device EI to the hall computer HC in such a manner that the upper base value abnormality signal and the lower base value abnormality signal can be distinguished. Therefore, in the hall computer HC and the abnormality alarm EI, it is possible to determine not only the presence or absence of an abnormality in the base value of the pachinko machine 10 but also the type of abnormality. As a result, the manager of the game hall can quickly take measures to deal with the type of base value abnormality that has occurred.

The abnormality annunciator EI gives an upper abnormality notification when an upper base value abnormality signal is received from the pachinko machine 10 and a lower abnormality notification when a lower base value abnormality signal is received from the pachinko machine 10. As a result, the base value is in an abnormal state in which it exceeds the upper threshold value (0.40) of the normal base range (0.35 to 0.40), and the base value is in the normal base range (0.35 to 0. It is possible to easily grasp that the abnormal state is below the lower threshold value (0.35) of 40). As a result, the burden of monitoring for grasping the abnormality of the base value by the manager of the game hall is reduced.

The main ROM 64 stores in advance a threshold value table 566 in which the upper threshold value and the lower threshold value of the normal base range (0.35 to 0.40) are set. As a result, it becomes possible for the main CPU 63 to determine the presence/absence of abnormality of the base value and the type of abnormality, and output the base value abnormality signal corresponding to the type of abnormality of the base value to the abnormality alarm EI. ing.

It should be noted that only one of the upper base value abnormality signal and the lower base value abnormality signal is external to the abnormality alarm EI having only one terminal for receiving the base value abnormality signal from the pachinko machine 10. You may select the connection mode to output. Specifically, the external output terminal TC4 of the external terminal board 97 is electrically connected to the abnormality alarm device EI, while the external output terminal TC5 is not electrically connected to the abnormality alarm device EI. May be In this case, only the upper base value abnormality signal can be externally output to the abnormality alarm EI, and the base value is above the upper threshold value (0.40) of the normal base range (0.35 to 0.40). Can be notified to the outside. The abnormality notification device EI outputs information including the upper base value abnormality signal received from the pachinko machine 10 and the identifier data of the abnormality notification device EI to the hall computer HC. Therefore, even in the hall computer HC, it can be understood that the base value exceeds the upper threshold value (0.40) of the normal base range (0.35 to 0.40). Further, the external output terminal TC5 in the external terminal board 97 may be electrically connected to the abnormality alarm device EI, while the external output terminal TC4 may not be electrically connected to the abnormality alarm device EI. .. In this case, only the lower base value abnormality signal can be externally output to the abnormality alarm EI so that the base value is below the lower threshold value (0.35) of the normal base range (0.35 to 0.40). It can be notified to the outside that there is. The abnormality notification device EI outputs information including the lower base value abnormality signal received from the pachinko machine 10 and the identifier data of the abnormality notification device EI to the hall computer HC. Therefore, even in the hall computer HC, it can be understood that the base value is below the lower threshold value (0.35) of the base normal range (0.35 to 0.40).

In addition, the base value in the current area 311 is within the base normal range (0.35 to 0) within one hour from the occurrence of the base value abnormality signal output trigger to the occurrence of the next base value abnormality signal output trigger. .40) above the upper threshold (0.40) and the base value of the current area 311 below the lower threshold (0.35) both occur later. Only the base value abnormality signal corresponding to the generated state may be externally output to the abnormality notification device EI. Specifically, in the abnormality flag setting process (FIG. 308), when the lower base value abnormality flag 568 is set to “1”, the base value of the current area 311 is in the base normal range (0.35 to 0). .40) above the upper threshold value (0.40) (step SK102: YES), the lower base value abnormality flag 568 is cleared to “0” and the upper base value abnormality flag 567 is set. Set "1". Also, in the situation where the upper base value abnormality flag 567 is set to "1", the base value of the current area 311 is below the lower threshold value (0.35) of the normal base range (0.35 to 0.40). If it is determined that there is (step SK105: YES), the upper base value abnormality flag 567 is cleared to "0" and the lower base value abnormality flag 568 is set to "1". As a result, in the abnormal signal output process (FIG. 309), only the base value abnormality signal corresponding to the abnormal state of the base value generated later is externally output to the abnormality annunciator EI. Further, the hall computer HC receives only the base value abnormal signal corresponding to the abnormal state of the base value that has occurred thereafter. Therefore, the manager of the game hall adjusts the state of the nails 24b scolded on the game board 24 or the like based on the base value abnormality signal corresponding to the latest base value in the current area 311 or the game ball. It is possible to confirm whether or not there is an action that illegally increases the total number of payouts.

Further, instead of the configuration in which the upper base value abnormality signal and the lower base value abnormality signal are externally output based on the latest base value and the past base value at the time of starting the supply of the operating power to the main CPU 63, the main CPU 63 A configuration may be employed in which the upper base value abnormality signal and the lower base value abnormality signal are externally output based on only the past base value when the supply of the operating power to the device is started. Specifically, in the base value initial output process (FIG. 310 ), first, the upper base value abnormality flag 567 and the lower base value abnormality flag 568 are cleared to “0”. As a result, based on the state of the upper base value abnormality flag 567 when the information of “1” is stored and held in the upper base value abnormality flag 567 before the supply of the operating power to the main CPU 63 is stopped. External output of the upper base value abnormality signal is avoided, and information “1” is stored in the lower base value abnormality flag 568 before the supply of operating power to the main CPU 63 is stopped. If so, it is avoided that the lower base value abnormality signal is externally output based on the state of the lower base value abnormality flag 568. In the base value initial output process (FIG. 310), the process of step SK303 is executed using the first to third history areas 312 to 314 as reference target areas, while the current area 311 is not set as a reference target area. Accordingly, the base value corresponding to the case where any of the past three base values stored in the first to third history areas 312 to 314 is out of the normal base range (0.35 to 0.40). While the abnormality flag (upper base value abnormality flag 567 or lower base value abnormality flag 568) is set to "1", the latest base value stored in the current area 311 is the base normal range (0.35 to 0). .40), the base value abnormality flag (upper base value abnormality flag 567 and lower base value abnormality flag 568) is not set to "1". In the configuration, in the abnormal signal output process executed in the base value initial output process (FIG. 310), the base value abnormal signal (upper base value abnormal signal and lower base value abnormal signal) based only on the past base value is used. Is externally output. If any of the past three base values stored in the first to third history areas 312 to 314 is out of the normal base range (0.35 to 0.40), the abnormal base value signal is notified. While the device EI outputs externally, the base value abnormal signal is externally output to the error annunciator EI even if the latest base value stored in the current area 311 is out of the normal base range (0.35 to 0.40). Not done. In this configuration, when the hall computer HC and the abnormality annunciator EI receive the upper base value abnormality signal or the lower base value abnormality signal immediately after the supply of the operating power to the pachinko machine 10 is started, the manager of the gaming hall is , It is possible to understand that the base value outside the normal base range (0.35 to 0.40) is one of the past base values stored in the first to third history areas 312 to 314. it can.

<86th Embodiment>
This embodiment differs from the 85th embodiment in that two lower threshold values are set in the normal base range. The configuration different from that of the 85th embodiment will be described below. The description of the same configuration as the 85th embodiment is basically omitted.

In the present embodiment, the lower first threshold “0.35” is set as the lower first threshold in the normal base range (0.35 to 0.40), and the lower second threshold is set. The lower second threshold value "0.30" is set as the threshold value of. Further, as in the 85th embodiment, the upper threshold value “0.40” is set as the upper threshold value in the normal base range.

In the present embodiment, the external output of the upper base value abnormality signal indicating that the base value exceeds the upper threshold value (0.40) to the abnormality alarm device EI and the base value of the lower first threshold value (0.35). Output to the abnormality alarm EI of the lower first base value abnormality signal indicating that the base value has fallen below the lower second base value (0.30) The abnormality signal is externally output to the abnormality alarm device EI.

FIG. 311(a) is a memory for external output of the upper base value abnormality signal, the lower first base value abnormality signal, and the lower second base value abnormality signal provided in the work area 221 for specific control in the present embodiment. It is an explanatory view for explaining an area. As shown in FIG. 311(a), an upper base value abnormality flag 567, a lower first base value abnormality flag 571, and a lower second base value abnormality flag 572 are provided in the work area 221 for specific control. .. The upper base value abnormality flag 567 indicates that an abnormal state in which the base value exceeds the upper threshold (0.40) of the base normal range (0.35 to 0.40) has occurred, as in the 85th embodiment. This is a flag that can be grasped by the main CPU 63. The lower first base value abnormality flag 571 is a flag that enables the main CPU 63 to grasp that an abnormal state in which the base value is lower than the lower first threshold value (0.35) of the base normal range has occurred. The lower second base value abnormality flag 572 is a flag that enables the main CPU 63 to know that an abnormal state in which the base value is lower than the lower second threshold value (0.30) of the base normal range has occurred. ..

In the present embodiment, a threshold table in which the upper threshold, the lower first threshold, and the lower second threshold of the normal base range (0.35 to 0.40) are set is stored in the main ROM 64 in advance. FIG. 311B is an explanatory diagram for explaining the threshold value table 573. As shown in FIG. 311(b), in the threshold table 573, "0.35" is set as the lower first threshold of the base value, and "0.30" is set as the lower second threshold of the base value. Is set. Further, “0.40” is set as the upper threshold of the base value. Since the threshold table 573 is stored in the main ROM 64 in advance, the main CPU 63 determines whether or not there is an abnormality in the base value and the type of abnormality, and outputs the base value abnormality signal corresponding to the type of abnormality in the base value. It is possible to externally output to the abnormality alarm EI.

In the main CPU 63, the base value stored in the current state area 311 and the first history area 312 to the third history area 314 (FIG. 126) in the calculation result storage area 234 is used as a base when the operation power supply to the main CPU 63 is started. Judgment processing for judging whether or not it is below the lower first threshold value (0.35) of the normal range (0.30 to 0.40), whether or not it is below the lower second threshold value (0.40) And a determination process of determining whether or not the upper threshold (0.40) is exceeded. Further, after the supply of the operating power to the main CPU 63 is started, the base value in the current area 311 (FIG. 126) in the calculation result storage area 234 is the lower first threshold value ( 0.35), a determination process for determining whether or not it is below, a determination process for determining whether or not it is below the lower second threshold value (0.40), and whether or not it is above the upper threshold value (0.40). A determination process for determining whether or not it is performed.

In these determination processes, when the base value is lower than the lower first threshold value (0.35), "1" is set to the lower first base value abnormality flag 571, and the base value is set to the lower first threshold value. When it is below the two threshold value (0.30), "1" is set to the lower second base value abnormality flag 572. Further, when the base value exceeds the upper threshold value (0.40), the upper base value abnormality flag 567 is set to "1".

Similar to the 85th embodiment, the output trigger of the base value abnormality signal is generated every predetermined time (specifically, 1 hour) after the supply of the operating power to the main CPU 63 is started. When the lower first base value abnormality flag 571 is set to "1", the lower first base value abnormality signal is notified to the abnormality alarm device EI based on the occurrence of the output of the base value abnormality signal. Is output to the lower second base value abnormality flag 572 and "1" is set in the lower second base value abnormality flag 572, the lower second base value is output based on the occurrence of the output of the relevant base value abnormality signal. External output of the value abnormality signal to the abnormality alarm EI is executed. Further, in the state where the upper base value abnormality flag 567 is set to “1”, the external output of the upper base value abnormality signal to the abnormality alarm EI is generated based on the occurrence of the output trigger of the base value abnormality signal. Executed.

The external output of the lower base value abnormality signal based on the base value falling below the lower limit (0.35) of the normal base range (0.35 to 0.40) has two levels depending on the degree of abnormality of the base value. With the configuration performed in (1), it is possible to use the abnormality notification device EI to grasp in detail the type of abnormal state of the base value when the base value falls below the lower limit of the normal base range.

FIG. 311C is an explanatory diagram for explaining a configuration for externally outputting the upper base value abnormality signal, the lower first base value abnormality signal, and the lower second base value abnormality signal. As shown in FIG. 311(c), the MPU 62 is provided with an output port 574. At the output port 574, a transmission buffer 575 in which 1 byte of base value abnormality data for outputting a base value abnormality signal to the external terminal board 97 is set, and 1 byte of base value abnormality data from the transmission buffer 575. In response to the transfer, the transmission shift register 576 that serially outputs the base value abnormality signal to the external terminal board 97 and the transfer of 1-byte base value abnormality data from the transmission buffer 575 to the transmission shift register 576 are completed. In this case, the transmission buffer 575 is provided with a settable flag 577 in which 1-bit data indicating that new base value abnormal data can be set is set. At the output port 574, the settable flag 577 is set to “1” when the transfer of the 1-byte base value abnormal data from the transmission buffer 575 to the transmission shift register 576 is completed.

At the output timing of the base value abnormal data, the main CPU 63 sets the base value abnormal data in the transmission buffer 575 on condition that “1” is set in the settable flag 577. Specifically, when the upper base value abnormality signal is externally output, 1-byte data “00000010” is set in the transmission buffer 575 as the upper base value abnormality data, and the lower first base value abnormality signal is externally output. In this case, 1-byte data of “00001010” is set in the transmission buffer 575 as the lower first base value abnormal data, and as the lower second base value abnormal data when the lower second base value abnormal signal is output to the outside. The 1-byte data “00101010” is set in the transmission buffer 575.

The abnormal base value data set in the transmission buffer 575 is transferred to the transmission shift register 576 and output to the external terminal board 97 by serial communication. When the upper base value abnormality data is set in the transmission buffer 575, the upper base value abnormality signal in which the data signal on the data signal line LN11 described later rises from the LOW state to the HI state once is output. .. In addition, when the lower first base value abnormal data is set in the transmission buffer 575, the lower first first base value abnormal data, which is described below, has two rises from the LOW state to the HI state in the data signal line LN11. When the base value abnormality signal is output and the lower second base value abnormality data is set in the transmission buffer 575, the rise of the data signal on the data signal line LN11 described later from the LOW state to the HI state occurs. The lower second base value abnormality signal, which is three times, is output. These three types of abnormal base value signals can be identified based on the waveform of the data signal on the data signal line LN11, which will be described later (the number of times of rising from the LOW state to the HI state).

The output port 574 is provided with a main side output terminal TA6 for outputting a base value abnormal signal, and the external terminal board 97 is for receiving the base value abnormal signal output from the main side output terminal TA5. The external receiving terminal TB6 is provided. The main output terminal TA6 and the external reception terminal TB6 are electrically connected to each other by using the data signal line LN11 and the clock signal line LN12. Each of these signal lines LN11 to LN12 is a signal line for transmitting a signal from the output port 574 of the MPU 62 to the external terminal board 97 by one-way communication. External output of the upper base value abnormality signal, the lower first base value abnormality signal, and the lower second base value abnormality signal is performed using the common data signal line LN11 and clock signal line LN12.

Here, the case where the base value abnormal signal is externally output will be described by taking as an example the case where the lower second base value abnormal signal is externally output. FIG. 312(a) shows a data signal transmission period from the output port 574 to the external terminal board 97, and FIG. 312(b) shows a clock signal transmission period from the output port 574 to the external terminal board 97. FIG. 312C shows the timing when the lower second abnormal data is set in the transmission buffer 575, and FIG. 312D shows the timing when the lower second abnormal data is transferred to the transmission shift register 576. 312(e) shows the state of the settable flag 577.

The main CPU 63 confirms that the settable flag 577 in the output port 574 is set to “1”, and then sets the transmission buffer 575 in the output port 574 at the timing t1 as shown in FIG. 312(c). The lower second base value abnormality data (specifically, 1-byte data of "00101010") is set. At the output port 574, the value of the settable flag 577 switches from “1” to “0” at the timing t1 as shown in FIG. 312(e).

Thereafter, at the output port 574, the lower second base value abnormality data set in the transmission buffer 575 is transferred to the transmission shift register 576 at the timing of t2 as shown in FIG. 312(d). Further, at the timing of t2, the value of the settable flag 577 switches from “0” to “1” as shown in FIG. 312(e). As a result, new base value abnormal data can be set in the transmission buffer 575.

Thereafter, as shown in FIGS. 312(a) and 312(b), the lower second base value abnormality signal is output from the output port 574 to the external terminal board 97 from the timing t3 to the timing t15. Be seen. Specifically, as shown in FIG. 312(b), the clock signal of the clock signal line LN12 that has been fixed to the HI state is dropped at the timing of t3, and t4, t5, t7, t9, t11, t13, The clock signal is output in such a manner that it is started up at the timing of t15 and t17. As shown in FIG. 312A, the data signal on the data signal line L11 is in the HI state from the timing t6 to the timing t8, the timing t10 to the timing t12, and the timing t14 to the timing t16. Is launched three times.

As shown in FIGS. 312(a) and 312(b), the timing at which the clock signal rises at the first time t4, the timing at which the clock signal rises at the second time t5, the timing at which the clock signal rises at the fourth time t9, and the timing at which the clock signal rises at the sixth time t13 The data signal at the timing t17 which rises at the 8th time is in the LOW state, and the data signal at the timing t7 when the clock signal rises at the third time, the timing t11 when the clock signal rises at the fifth time, and the timing t15 when the clock signal rises at the seventh time is HI. It is in a state. As described above, in the external output of the lower second base value abnormality signal, the signal is output from the output port 574 to the external terminal board 97 in the order of “00101010”.

The data signal and the clock signal received at the external receiving terminal TB6 of the external terminal board 97 are output from the external output terminal TC6 to the abnormality alarm EI. As a result, the pachinko machine 10 outputs the lower second base value abnormality signal to the abnormality alarm EI. The abnormality annunciator EI recognizes that the lower second base value abnormality signal has been received based on that the data signal received from the external terminal board 97 has risen three times.

When any of the upper base value abnormality signal, the lower first base value abnormality signal and the lower second base value abnormality signal is received from the pachinko machine 10, the abnormality alarm EI corresponds to the received base value abnormality signal. In this manner, the abnormality notification for notifying the abnormality of the base value in the pachinko machine 10 is performed. Specifically, when the upper base value abnormality data is received from the pachinko machine 10, the upper abnormality notification indicating that the base value of the pachinko machine 10 exceeds the upper threshold value (0.40) is performed. Further, when the lower first base value abnormality data is received from the pachinko machine 10, the lower first abnormality notification indicating that the base value of the pachinko machine 10 is below the lower first threshold value (0.35). When the lower second base value abnormality data is received from the pachinko machine 10, the base value of the pachinko machine 10 is lower than the lower second threshold value (0.30). 2 Abnormality notification is performed.

The abnormality annunciator EI receives the base value abnormality signal (either the upper base value abnormality signal, the lower first base value abnormality signal or the lower second base value abnormality signal) received from the pachinko machine 10, and the abnormality alarm EI. And the information including the identifier data is output to the hall computer HC. The base value abnormality signal is output from the abnormality alarm device EI to the hall computer HC in such a manner that the type of the base value abnormality signal can be grasped. The hall computer HC grasps the corresponding pachinko machine 10 based on the identifier data received from the abnormality notification device EI, and also determines whether or not there is an abnormality in the base value based on the base value abnormality signal received from the abnormality notification device EI. Figure out the type. The manager of the game hall can also grasp the presence/absence of an abnormality in the base value in the pachinko machine 10 and the type of the abnormality in the base value in the hall computer HC as well.

As described above, the upper base value abnormality signal, the lower first base value abnormality signal, and the lower second base value abnormality signal use the common data signal line and clock signal line (data signal line LN11 and clock signal line LN12). It is output to the external terminal board 97 by utilizing it. Therefore, the number of data signal lines and clock signal lines can be reduced as compared with the configuration in which the data signal lines and clock signal lines for outputting each base value abnormality signal to the external terminal board 97 are separately provided. It is possible to output three types of base value abnormality signals. Further, the pachinko machine 10 is also connected to an abnormality annunciator EI having only one terminal for receiving a base value abnormality signal from the pachinko machine 10 to transmit three types of base value abnormality signals. It is possible. Accordingly, the abnormality alarm EI can perform the upper side abnormality notification, the lower side first abnormality notification, and the lower side second abnormality notification that enable detailed understanding of the type of abnormality of the base value in the pachinko machine 10. In addition, the presence/absence of abnormality in the base value and the type of abnormality can be grasped in detail in the hall computer HC.

After the main CPU 63 sets the base value abnormal data in the transmission buffer 575, serial output of the base value abnormal signal corresponding to the base value abnormal data to the external terminal board 97 does not require control by the main CPU 63. In a manner, it proceeds at output port 574. As a result, the time required for the process for externally outputting the base value abnormality signal in the main CPU 63 is shortened.

Next, the abnormality flag setting process executed by the main CPU 63 will be described with reference to the flowchart of FIG. The abnormality flag setting process is executed in step SJ904 of the external information setting process (FIG. 307) and step SK305 of the base value initial output process (FIG. 310) in the 85th embodiment. Further, the processes of steps SK401 to SK409 in the abnormality flag setting process are executed by using the specific control program and the specific control data in the main CPU 63.

In steps SK401 to SK403, the same processing as steps SK101 to SK103 of the abnormality flag setting processing (FIG. 308) in the 85th embodiment is executed. Specifically, first, it is determined whether or not the upper base value abnormality flag 567 in the specific control work area 221 is set to "1" (step SK401). As described above, the upper side base value abnormality flag 567 causes the main side CPU 63 to indicate that an abnormal state in which the base value exceeds the upper side threshold value (0.40) of the base normal range (0.35 to 0.40) has occurred. It is a flag that can be grasped. If a negative determination is made in step SK401, it is determined whether or not the base value in the current area 311 exceeds the upper threshold value (0.40) set in the threshold value table 573 (step SK402), and the base If the value is above the upper threshold (step SK402: YES), the upper base value abnormality flag 567 is set to "1" (step SK403).

If an affirmative determination is made in step SK401 or a negative determination is made in step SK402, "1" is set to the lower first base value abnormality flag 571 in the specific control work area 221. It is determined whether or not there is (step SK404). As described above, the lower first base value abnormality flag 571 indicates that an abnormal state in which the base value falls below the lower first threshold value (0.35) of the base normal range (0.35 to 0.40) has occurred. Is a flag that enables the main CPU 63 to grasp. When a negative determination is made in step SK404, it is determined whether or not the base value in the current area 311 is lower than the lower first threshold value (0.35) set in the threshold value table 573 (step SK405), When the base value is below the lower first threshold value (step SK405: YES), "1" is set to the lower first base value abnormality flag 571 (step SK406).

If a positive determination is made in step SK404, a negative determination is made in step SK405, or if the process of step SK406 is performed, the lower second base value abnormality flag in the work area 221 for specific control is set. It is determined whether "1" is set in 572 (step SK407). As described above, the lower second base value abnormality flag 572 has an abnormal state in which the base value is below the lower second threshold value (0.30) of the base normal range (0.35 to 0.40). This is a flag that enables the main CPU 63 to recognize the fact. When a negative determination is made in step SK407, it is determined whether or not the base value in the current area 311 is below the lower second threshold value (0.30) set in the threshold value table 573 (step SK408), If the base value is below the lower second threshold value (step SK408: YES), the lower second base value abnormality flag 572 is set to "1" (step SK409), and this abnormality flag setting process is performed. To finish.

Next, the abnormal signal output process executed by the main CPU 63 will be described with reference to the flowchart of FIG. 314. The abnormal signal output process is executed in step SJ907 of the external information setting process (FIG. 307) and step SK308 of the base value initial output process (FIG. 310) in the 85th embodiment. Further, the processes of steps SK501 to SK509 in the abnormal signal output process are executed by using the specific control program and the specific control data in the main CPU 63.

In steps SK501 to SK503, the same processing as steps SK201 to SK203 of the abnormal signal output processing (FIG. 309) in the 85th embodiment is executed. Specifically, when "1" is set in the upper base value abnormality flag 567 in the work area 221 for specific control (step SK501: YES), external output processing of the upper base value abnormality signal is executed (step). SK502). In the external output processing of the upper base value abnormality signal, the upper base value abnormality data (specifically, 1-byte data “00000010”) is set in the transmission buffer 575 at the output port 574. As a result, the upper base value abnormality signal is externally output to the abnormality alarm EI through serial communication via the external terminal board 97. The abnormality annunciator EI recognizes that the upper base value abnormality signal has been received based on that the data signal received from the pachinko machine 10 has risen once. After that, the upper base value abnormality flag 567 is cleared to "0" (step SK503).

If a negative determination is made in step SK501, or if the process of step SK503 is performed, whether or not "1" is set in the lower first base value abnormality flag 571 in the work area 221 for specific control is determined. It is determined (step SK504). When "1" is set to the lower first base value abnormality flag 571 (step SK504: YES), the lower first base value abnormality signal is externally output (step SK505). In the external output process of the lower first base value abnormality signal, the lower first base value abnormality data (specifically, 1-byte data “000010110”) is set in the transmission buffer 575 at the output port 574. As a result, the lower first base value abnormality signal is externally output to the abnormality alarm device EI through serial communication via the external terminal board 97. The abnormality annunciator EI recognizes that the lower first base value abnormality signal has been received based on the fact that the data signal received from the pachinko machine 10 has risen twice. After that, the lower first base value abnormality flag 571 is cleared to "0" (step SK506).

If a negative determination is made in step SK504, or if the process of step SK506 is performed, whether or not "1" is set in the lower second base value abnormality flag 572 in the work area 221 for specific control is determined. It is determined (step SK507). When "1" is set to the lower second base value abnormality flag 572 (step SK507: YES), an external output process of the lower second base value abnormality signal is executed (step SK508). In the external output processing of the lower second base value abnormality signal, the lower second base value abnormality data (specifically, 1-byte data of “00101010”) is set in the transmission buffer 575 at the output port 574. As a result, the lower second base value abnormality signal is externally output to the abnormality indicator EI through serial communication via the external terminal board 97. The abnormality annunciator EI recognizes that the lower second base value abnormality signal has been received based on the fact that the data signal received from the pachinko machine 10 has risen three times. After that, the lower second base value abnormality flag 572 is cleared to "0" (step SK509), and this abnormality signal output processing ends.

According to this embodiment described in detail above, the following excellent effects are exhibited.

When the base value is lower than the lower first threshold value (0.35), the lower first base value abnormality signal is externally output to the abnormality alarm device EI, and the base value is lower than the lower second threshold value (0.30). ), the lower second base value abnormality signal is externally output to the abnormality alarm EI. The abnormality notification device EI outputs information including the base value abnormality signal received from the pachinko machine 10 and the identifier data of the abnormality notification device EI to the hall computer. The base value abnormality signal is output from the abnormality alarm device EI to the hall computer HC in such a manner that the type of the base value abnormality signal can be grasped. The external output of the lower side base value abnormality signal based on the base value falling below the lower limit (0.35) of the normal base range (0.35 to 0.40) has two levels according to the degree of abnormality of the base value. According to the configuration performed in (1), the type of abnormal state of the base value when the base value falls below the lower limit of the normal base range can be grasped in detail by the hall computer HC and the abnormality alarm EI. As a result, the manager of the game hall can quickly take measures to deal with the type of base value abnormality that has occurred.

When the base value is below the lower second threshold value (0.30), the lower second base value abnormality signal is externally output. As a result, it is possible to grasp that the abnormality of the base value is serious in the hall computer HC and the abnormality annunciator EI, and notice that the base value is in a serious abnormal state below the second threshold value (0.30). It is possible to reduce the possibility of being left unattended.

The upper base value abnormality signal, the lower first base value abnormality signal, and the lower second base value abnormality signal use the common data signal line and clock signal line (data signal line LN11 and clock signal line LN12) to notify the abnormality. It is externally output to the container EI. Therefore, the number of data signal lines and clock signal lines can be reduced as compared with the configuration in which the data signal lines and clock signal lines for outputting each base value abnormality signal to the external terminal board 97 are separately provided. It is possible to output three types of base value abnormality signals. Further, the pachinko machine 10 is also connected to an abnormality annunciator EI having only one terminal for receiving a base value abnormality signal from the pachinko machine 10 to transmit three types of base value abnormality signals. It is possible.

After the main CPU 63 sets the base value abnormal data in the transmission buffer 575, serial output of the base value abnormal signal corresponding to the base value abnormal data to the external terminal board 97 does not require control by the main CPU 63. In a manner, it proceeds at output port 574. As a result, the time required for the process for externally outputting the base value abnormality signal in the main CPU 63 is shortened.

The main ROM 64 stores in advance a threshold table 573 in which an upper threshold value, a lower first threshold value, and a lower second threshold value of the normal base range (0.35 to 0.40) are set. As a result, it becomes possible for the main CPU 63 to determine the presence/absence of abnormality of the base value and the type of abnormality, and output the base value abnormality signal corresponding to the type of abnormality of the base value to the abnormality alarm EI. ing.

The upper base value abnormality signal, the lower first base value abnormality signal, and the lower second base value abnormality signal can be identified based on the waveform (the number of rising edges) of the data signal output from the main output terminal TA6. Instead of the above configuration, the base value abnormality signal may be identified by the number of times the pulsed data signal is output. Specifically, when the base value abnormality signal output trigger occurs while the upper base value abnormality flag 567 is set to "1", the external information setting processing (FIG. 307) is performed once. At, the pulsed data signal is externally output to the abnormality alarm EI. When the output trigger of the base value abnormality signal is generated while the lower first base value abnormality flag 571 is set to “1”, the external information setting processing (FIG. 307) is performed twice. And output a pulsed data signal to the abnormality alarm EI externally. When the output trigger of the base value abnormality signal occurs in the state where the lower second base value abnormality flag 572 is set to “1”, the external information setting processing (FIG. 307) is performed three times. And output a pulsed data signal to the abnormality alarm EI externally. Each time the abnormality annunciator EI receives the base value abnormality signal, the abnormality annunciator EI outputs information including the base value abnormality signal and the identifier data of the abnormality annunciator EI to the hall computer HC. In the configuration, the hall computer HC and the abnormality annunciator EI recognize that the upper base value abnormality signal has been received when the pulsed data signal is received independently, and receive the pulsed data signal twice consecutively. It is possible to know that the lower first base value abnormal signal has been received, and that the lower second base value abnormal signal has been received when the pulsed data signal has been received three times in succession. it can.

Further, external output of the upper base value abnormality signal, external output of the lower first base value abnormality signal, and external output of the lower second base value abnormality signal are performed using a common data signal line and clock signal line. Instead of the configuration, a data signal line and a clock signal line are used in which the external output of the upper base value abnormality signal, the lower first base value abnormality signal and the lower second base value abnormality signal are different from each other. It may be configured to be performed. In this configuration, while the waveform of the upper base value abnormal signal, the waveform of the lower first base value abnormal signal, and the waveform of the lower second base value abnormal signal are the same, the base value is within the base normal range (0.35 to 0.40) above the upper threshold value (0.40), an abnormal state in which the base value is below the lower first threshold value (0.35), and a base value below the lower second threshold value (0.35). It is possible to execute the external output of the base value abnormality signal in such a manner as to be able to discriminate the abnormal state of less than 0.30).

Further, the configuration for externally outputting the three types of base value abnormality signals to the abnormality alarm device EI is not limited to the configuration for externally outputting the base value abnormality signal by serial communication. For example, the MPU 62 and the external terminal board 97 may be connected to each other through one signal path capable of outputting a 2-bit unit base value abnormality signal by parallel communication. In this case, for example, when the base value exceeds the upper threshold value (0.40) of the normal base range (0.35 to 0.40), the data signal of "01" in binary notation is sent to the abnormality alarm EI. When the base value is lower than the lower first threshold value (0.35), a data signal of "10" in binary notation is externally output to the abnormality alarm EI and the base value is lower. When it is below the second threshold value (0.30), the data signal of “11” in binary notation is externally output to the abnormality alarm device EI. The abnormality alarm device EI outputs to the hall computer HC information including the data signal of any of “01”, “10” and “11” received from the pachinko machine 10 and the identifier data of the abnormality alarm device EI. .. As a result, in the hall computer HC and the abnormality alarm EI, an abnormal state in which the base value exceeds the upper threshold value, an abnormal state in which the base value falls below the lower first threshold value, and a base value in the lower second threshold value It is possible to grasp the abnormal state of the base value in a manner in which it can be discriminated from the abnormal state that is lower than.

<87th Embodiment>
In this embodiment, the number and types of base value abnormality signals that can be output to the abnormality alarm EI are different from those in the 85th embodiment. The configuration different from that of the 85th embodiment will be described below. The description of the same configuration as the 85th embodiment is basically omitted.

In the present embodiment, it is possible to externally output the common base value abnormality signal, the upper base value abnormality signal, and the lower base value abnormality signal as the signal indicating the abnormality of the base value to the abnormality alarm EI. .. The common base value abnormality signal is commonly output to the outside when the base value is above the upper threshold value (0.40) and when the base value is below the lower threshold value (0.35). This is a base value abnormality signal. Similar to the 85th embodiment, the upper base value abnormality signal is a base value abnormality signal output to the outside when the base value exceeds the upper threshold value (0.40), and the lower base value abnormality signal is This is a base value abnormality signal externally output when the base value is below the lower threshold value (0.35).

315(a) and 315(b) are block diagrams for explaining a configuration for externally outputting the common base value abnormality signal, the upper base value abnormality signal, and the lower base value abnormality signal in the present embodiment. .. As shown in FIGS. 315(a) and 315(b), the MPU 62 has a main output terminal TA4 for outputting an upper base value abnormality signal from the main CPU 63, as in the 85th embodiment. A main output terminal TA5 for outputting a lower base value abnormality signal from the main CPU 63 is provided. The external terminal board 97 has an external receiving terminal TB4 for receiving an upper base value abnormal signal and an external receiving terminal for receiving a lower base value abnormal signal, as in the 85th embodiment. A terminal TB5 is provided. Similar to the 85th embodiment, the main output terminal TA4 and the external reception terminal TB4 are electrically connected using the upper data signal line LN7 and the upper clock signal line LN8, and the main output The terminal TA5 and the external receiving terminal TB5 are electrically connected by using the lower data signal line LN9 and the lower clock signal line LN10.

The MPU 62 in this embodiment is provided with a main output terminal TA7 for outputting a common base value abnormality signal from the main CPU 63, and the external terminal board 97 in this embodiment has the common base value abnormality. An external receiving terminal TB7 for receiving a signal is provided. The main output terminal TA7 and the external reception terminal TB7 are electrically connected to each other by using the common data signal line LN13 and the common clock signal line LN14. These signal lines LN7 to LN10, LN13, LN14 are all signal lines for transmitting signals from the main CPU 63 to the external terminal board 97 by one-way communication.

A common base value abnormality signal is transmitted by serial communication from the main CPU 63 to the external terminal board 97 using the common data signal line LN13. In this case, each 1-bit division of the common base value abnormality signal by serial communication is indicated by the clock signal transmitted from the main CPU 63 to the external terminal board 97 using the common clock signal line LN14.

Similarly to the 85th embodiment, the external terminal board 97 includes an external output terminal TC4 for outputting an upper base value abnormality signal received by the external reception terminal TB4 to the abnormality annunciator EI, and an external side. An external output terminal TC5 for outputting the lower base value abnormality signal received at the reception terminal TB5 to the abnormality annunciator EI is provided. Further, the external terminal board 97 in the present embodiment is provided with an external output terminal TC7 for outputting the common base value abnormality signal received by the external reception terminal TB7 to the abnormality annunciator EI.

In the present embodiment, there are a connection mode that outputs only the common base value abnormality signal to the abnormality alarm device EI and a connection mode that outputs the upper base value abnormality signal and the lower base value abnormality signal to the abnormality alarm device EI. Can be selected in the game hall.

In the connection mode in which only the common base value abnormality signal is externally output to the abnormality alarm device EI, as shown in FIG. 315(a), the external output terminal TC7 of the external terminal board 97 and the abnormality alarm device EI are electrically connected. On the other hand, the external output terminals TC4, TC5 and the abnormality alarm EI are not electrically connected. The abnormality annunciator EI provides a common abnormality notification for notifying an abnormality of the base value of the pachinko machine 10 based on the reception of the common base value abnormality signal from the pachinko machine 10. Further, the abnormality notification device EI outputs information including the common base value abnormality signal received from the pachinko machine 10 and the identifier of the abnormality notification device EI to the hall computer HC. As a result, the abnormality alarm EI and the hall computer HC can recognize that the base value of the pachinko machine 10 is out of the normal base range (0.35 to 0.40).

In the connection mode in which the upper base value abnormality signal and the lower base value abnormality signal are externally output to the abnormality alarm device EI, as shown in FIG. 315(b), the external output terminals TC4 and TC5 on the external terminal board 97 are connected to each other. The abnormality indicator EI is electrically connected, while the external output terminal TC7 and the abnormality indicator EI are not electrically connected.

In the abnormality annunciator EI, the base value in the pachinko machine 10 is set to the upper threshold value (0.40) of the base normal range (0.35 to 0.40) based on the reception of the upper base value abnormality signal from the pachinko machine 10. An upper abnormality notification is made to notify that the condition is above. Further, the abnormality notification device EI outputs information including the upper base value abnormality signal received from the pachinko machine 10 and the identifier of the abnormality notification device EI to the hall computer HC. This allows the abnormality alarm EI and the hall computer HC to know that the base value of the pachinko machine 10 is above the upper threshold value (0.40) of the normal base range (0.35 to 0.40). Becomes

In the abnormality alarm device EI, the base value in the pachinko machine 10 is the lower threshold value (0.35 to 0.45) of the base normal range (0.35 to 0.40) based on the reception of the lower base value abnormality signal from the pachinko machine 10. ) Is issued, a lower-side abnormality notification is performed to notify that the vehicle is in a state of falling below. Further, the abnormality notification device EI outputs information including the lower base value abnormality signal received from the pachinko machine 10 and the identifier of the abnormality notification device EI to the hall computer HC. Thus, the abnormality alarm EI and the hall computer HC grasp that the base value of the pachinko machine 10 is below the lower threshold value (0.35) of the normal base range (0.35 to 0.40). It will be possible.

In this way, a connection mode in which one type of base value abnormality signal (common base value abnormality signal) is externally output to the abnormality alarm device EI using one signal path, and two types of connection methods are used using two signal paths. A terminal for receiving the base value abnormality signal from the pachinko machine 10 can be set to 1 by selecting a connection mode for externally outputting the base value abnormality signal (the upper base value abnormality signal and the lower base value abnormality signal). It is possible to transmit the base value abnormality signal to both the abnormality notification device EI having only one and the abnormality notification device EI having two terminals for receiving the base value abnormality signal from the pachinko machine 10. It is possible.

In the connection mode in which the common base value abnormality signal is externally output to the abnormality alarm device EI (FIG. 315(a)), the base value of the pachinko machine 10 in the abnormality alarm device EI and the hall computer HC is in the normal base range (0.35). .About.0.40) can be grasped. As a result, the manager of the game hall is provided with an opportunity to perform maintenance for adjusting the state of the nails 24b scrambled on the game board 24 of the pachinko machine 10 and illegally increase the total payout number of game balls. It is possible to give an opportunity to confirm the presence or absence of such behavior.

In the connection mode in which the upper base value abnormality signal and the lower base value abnormality signal are externally output to the abnormality alarm device EI (FIG. 315(b)), the base value of the pachinko machine 10 in the abnormality alarm device EI and the hall computer HC is set. It is possible to understand that the upper threshold (0.40) of the base normal range (0.35-0.40) is exceeded, and the total payout number of gaming balls is illegal to the manager of the gaming hall. It is possible to give an opportunity to confirm the presence or absence of an action that raises the base value, and the base value is below the lower threshold value (0.35) of the normal base range (0.35 to 0.40). As a result, the manager of the game hall can be given an opportunity to perform maintenance for adjusting the state of the nails 24b scrambled on the game board 24 in the pachinko machine 10.

Next, the abnormal signal output process executed by the main CPU 63 will be described with reference to the flowchart in FIG. The abnormal signal output process is executed in step SJ907 of the external information setting process (FIG. 307) and step SK308 of the base value initial output process (FIG. 310) in the 85th embodiment. Further, the processes of steps SK601 to SK608 in the abnormal signal output process are executed by using the specific control program and the specific control data in the main CPU 63.

In the abnormal signal output processing, it is first determined whether or not "1" is set in either the upper base value abnormality flag 567 or the lower base value abnormality flag 568 in the work area 221 for specific control (step SK601). ). When an affirmative determination is made in step SK601, external output processing of the common base value abnormality signal is executed (step SK602). In the external output processing of the common base value abnormality signal, in the situation where the main-side output terminal TA7 of the MPU 62 outputs a pulsed clock signal to the common clock signal line LN14, the main-side output terminal TA7 outputs the common data signal line. After the signal output to the LN 13 is raised from LOW to HI, the signal is lowered from HI to LOW. Accordingly, when the external output terminal TC7 of the external terminal board 97 and the abnormality annunciator EI are electrically connected, the common base value abnormality signal is externally output to the abnormality annunciator EI via the external terminal board 97. Is output. As described above, the abnormality notification device EI outputs information including the common base value abnormality signal received from the pachinko machine 10 and the identifier data of the abnormality notification device EI to the hall computer HC. As a result, it is possible to grasp that the hall computer HC and the abnormality alarm EI are in an abnormal state in which the base value is out of the normal base range (0.35 to 0.40).

Then, in steps SK603 to SK608, the same processes as the processes of steps SK201 to SK206 in the abnormal signal output process (FIG. 309) of the 85th embodiment are executed. Specifically, when the upper base value abnormality flag 567 in the work area 221 for specific control is set to "1" (step SK603: YES), the external output processing of the upper base value abnormality signal is executed (step). SK604). In the external output processing of the upper base value abnormality signal, in the situation where the pulsed clock signal is output from the main output terminal TA4 of the MPU 62 to the upper clock signal line LN8, the main output terminal TA4 outputs the upper data signal line. After the signal output to LN7 is raised from LOW to HI, the signal is lowered from HI to LOW. As a result, when the external output terminal TC4 of the external terminal board 97 and the abnormality indicator EI are electrically connected, the upper base value abnormality signal is sent to the abnormality indicator EI via the external terminal board 97. It is output externally. As described above, the abnormality notification device EI outputs information including the upper base value abnormality signal received from the pachinko machine 10 and the identifier data of the abnormality notification device EI to the hall computer HC. Thereby, it is possible to grasp that the hall computer HC and the abnormality alarm EI are in an abnormal state in which the base value exceeds the upper threshold value (0.40) of the normal base range (0.35 to 0.40). You can Then, the upper base value abnormality flag 567 is cleared to "0" (step SK605).

If a negative determination is made in step SK603, or if the process of step SK605 is performed, it is determined whether or not "1" is set in the lower base value abnormality flag 568 in the work area 221 for specific control. The determination is made (step SK606). When "1" is set to the lower base value abnormality flag 568 (step SK606: YES), external output processing of the lower base value abnormality signal is executed (step SK607). In the external output processing of the lower base value abnormality signal, the main output terminal TA5 of the MPU 62 outputs a pulsed clock signal to the lower clock signal line LN10 from the main output terminal TA5 of the lower side. After the signal output to the data signal line LN9 is raised from LOW to HI, the signal is lowered from HI to LOW. As a result, when the external output terminal TC5 of the external terminal board 97 and the abnormality annunciator EI are electrically connected, the lower base value abnormality signal is transmitted to the abnormality annunciator EI via the external terminal board 97. Is output externally. As described above, the abnormality notification device EI outputs information including the lower base value abnormality signal received from the pachinko machine 10 and the identifier data of the abnormality notification device EI to the hall computer HC. This makes it possible to grasp that the hall computer HC and the abnormality alarm EI are in an abnormal state in which the base value is below the lower threshold value (0.35) of the base normal range (0.35 to 0.40). be able to. After that, the lower base value abnormality flag 568 is cleared to "0" (step SK608), and this abnormality signal output processing is ended.

According to this embodiment described in detail above, the following excellent effects are exhibited.

The external terminal board 97 has an external output terminal TC7 for externally outputting the common base value abnormality signal received from the main CPU 63 to the abnormality annunciator EI and an upper base value abnormality signal received from the main CPU 63. An external output terminal TC4 for external output to the device EI and an external output terminal TC5 for external output of the lower base value abnormality signal received from the main CPU 63 to the abnormality annunciator EI are provided. As a connection mode between the external terminal board 97 and the abnormality alarm device EI, a connection mode in which only the common base value abnormality signal is externally output using one signal path, and an upper base value abnormality signal and a lower signal using the two signal paths are used. A connection mode that outputs a side base value abnormality signal can be selected. Accordingly, the abnormality alarm EI having one terminal for receiving the base value abnormality signal from the pachinko machine 10 and the two terminals for receiving the base value abnormality signal from the pachinko machine 10 are provided. It is possible to notify the abnormality of the base value to any of the abnormality annunciators EI that are present.

When the external terminal board 97 and the abnormality indicator EI are electrically connected using one signal path, the abnormality indicator EI is the common base value abnormality signal received from the pachinko machine 10 and the abnormality indicator. Information including the EI identifier data is output to the hall computer HC. Accordingly, it is possible to grasp that the hall computer HC and the abnormality alarm EI are in an abnormal state in which the base value is out of the normal base range (0.35 to 0.40). Further, when the external terminal board 97 and the abnormality indicator EI are electrically connected using two signal paths, the abnormality indicator EI receives the upper base value abnormality signal and the lower base signal received from the pachinko machine 10. Information including any of the value abnormality signals and the identifier data of the abnormality alarm device EI is output to the hall computer HC. As a result, the hall computer HC and the abnormality alarm EI are in an abnormal state in which the base value exceeds the upper threshold value (0.40) of the base normal range (0.35 to 0.40), and the base value is the base value. It is possible to understand that the abnormal state is below the lower threshold (0.35) of the normal range (0.35 to 0.40).

<88th Embodiment>
This embodiment differs from the 77th embodiment in that the demonstration effect is started at irregular timing. The configuration different from that of the 77th embodiment will be described below. Note that the description of the same configuration as the 77th embodiment is basically omitted.

Similar to the 77th embodiment, the demonstration effect is started at the timing when the value of the timer counter 554a for starting the demo reaches the maximum value in the start waiting state. In this embodiment, there are a plurality (specifically, four types) of numerical value information set as the maximum value of the timer counter 554a for starting a demonstration. While the value of the demo start timer counter 554a has reached the maximum value, the demo start timer counter 554a is updated (step SI601 of the sound-light timer interrupt process (FIG. 284)), and the demo start timer counter is executed. Every time the value of 554a is cleared to "0", the maximum value lottery for determining the maximum value of the timer counter 554a for starting the demonstration is performed. Then, the maximum value of the demo start timer counter 554a is changed in a manner corresponding to the lottery result of the maximum value lottery. Therefore, the timing at which the value of the demo start timer counter 554a reaches the maximum value becomes irregular, and the demonstration effect can be started at irregular timing.

FIG. 317 is an explanatory diagram for explaining the electrical configuration of the sound emission control board 351 in the present embodiment. As shown in FIG. 317, the sound emission side MPU 352 and the random number memory 578 are mounted on the sound emission control board 351. As described in the forty-ninth embodiment, the sound/light side MPU 352 includes the sound/light side CPU 353, the sound/light side ROM 354, and the sound/light side RAM 355. Similar to the 77th embodiment, the backup power for storing and holding information is not supplied to the sound/light side RAM 355 in the state where the supply of the operating power to the pachinko machine 10 is stopped.

The sound-light side RAM 355 in this embodiment is not provided with the non-initialization target area 554 and the initialization target area 555 in the 77th embodiment. As shown in FIG. 317, the sound-light side RAM 355 is provided with a demo start timer counter 554a, a maximum value counter 579, a waiting state timer counter 555a, and a waiting state flag 555b.

The demo start timer counter 554a is a timer counter that enables the sound-light side CPU 353 to grasp the start timing of the demonstration effect in the start waiting state, as in the 77th embodiment. Further, the maximum value counter 579 is a counter that enables the sound-light side CPU 353 to grasp the maximum value of the demonstration starting timer counter 554a. In the maximum value counter 579, any numerical value information of “2599”, “2999”, “3399” and “3799” is set according to the result of the maximum value lottery.

Similar to the 77th embodiment, the timer counter 555a for waiting state has a predetermined period (specifically, 10) during which neither the game turning effect nor the opening/closing execution mode effect is executed. It is a timer counter that allows the sound-light side CPU 353 to know that the sound light-side CPU 353 has reached the start time, and the waiting state flag 555b is a flag that allows the sound-light side CPU 353 to know that it is in the start waiting state. The maximum value of the waiting state timer counter 555a is preset to "120,000".

The random number memory 578 is a memory (that is, a volatile storage means) such as an SRAM and a DRAM that needs to be supplied with electric power from the outside to retain the storage, and is used for both reading and writing. The random number memory 578 is provided with a lottery random number counter 578a for storing lottery random number information used in the maximum value lottery described above. The lottery random number counter 578a is a loop counter that is incremented by 1 in the numerical range of “0” to “255” and returns to “0” after reaching the maximum value.

The lottery random number information stored in the lottery random number counter 578a is updated in the lottery random number updating process (step SK718 of the sound-light side start-up process (FIG. 318)) described later. In the lottery random number update process, the sound-light side CPU 353 reads the lottery random number information stored in the lottery random number counter 578a, and after performing the process of adding “1” to the read lottery random number information. A process for overwriting the random number information for lottery 578a with the random number information for lottery after the addition of "1" is executed. In the lottery random number update process, when the lottery random number information after the addition of “1” exceeds the maximum value (specifically, “255”), the lottery random number counter 578a is used as the updated lottery random number information. The numerical information of "0" is overwritten.

The random number memory 578 is supplied with backup power for storing and holding information in a state in which the supply of operating power to the pachinko machine 10 is stopped. Therefore, the random number information for lottery in the lottery random number counter 578a is stored and held even when the supply of operating power to the pachinko machine 10 is stopped. However, the present invention is not limited to this, and the random number memory 578 may be an EEPROM or the like that does not require external power supply to store and hold information.

Next, the sound-light side startup processing executed by the sound-light side CPU 353 in this embodiment will be described with reference to the flowchart in FIG. 318. The sound-light side startup process is executed when the supply of operating power to the pachinko machine 10 is started.

In the sound/light side start-up process, first, a sound/light side RAM clearing process is executed (step SK701). In the sound-light side RAM clearing process, "0" is cleared and all the storage areas in the sound-light side RAM 355 are cleared and initialized. As described above, when the supply of the operating power to the pachinko machine 10 is stopped, the backup power is not supplied to the sound/light side RAM 355. Therefore, immediately after the supply of the operating power to the pachinko machine 10 is started, the storage area of the sound/light side RAM 355 is in an indefinite state. By executing the sound-light side RAM clearing process in step SK701, the undefined state in the storage area of the sound-light side RAM 355 can be eliminated.

After that, in steps SK702 to SK706, the same processes as steps SI504 to SI508 of the sound-light side startup process (FIG. 283) in the 77th embodiment are executed. If it is determined in step SK706 that any of the return commands has been received from the main CPU 63, the sound/light side RAM initial setting process is executed (step SK707). In the sound-light side RAM initial setting process, all storage areas of the sound-light side RAM 355 are cleared to “0” and initialized. In addition, when "0" is cleared in all the storage areas of the sound-light side RAM 355 and the initial setting is performed, when the update notification is performed, the update notification is ended, and the confirmation notification is performed. Ends the notification at the time of confirmation.

In the sound-light-side RAM initial setting process in step SK707, the value of the demo start timer counter 554a is cleared to "0". In the present embodiment, regardless of whether the return command received by the sound-light side CPU 353 from the main CPU 63 is a normal return command, a check return command, an update return command, or a clear return command, the sound-light side RAM is used. Initialization initialization processing is executed and the value of the timer counter 554a for starting the demonstration is cleared to "0". Further, in the sound light side RAM initial setting processing in step SK707, the value of the maximum value counter 579 in the sound light side RAM 355 is cleared to “0”. The maximum value counter 579 is set to the maximum value of the demo start timer counter 554a in a maximum value setting process (step SK716) described later before the update of the demo start timer counter 554a is started.

After executing the sound-light side RAM initial setting processing in step SK707, "1" is set to the waiting state flag 555b in the sound-light side RAM 355 to start the start waiting state (step SK708). Then, in steps SK709 to SK715, the same processing as steps SI511 to SI517 of the sound-light side startup processing (FIG. 283) in the 77th embodiment is executed.

When the normal return notification setting process is executed in step SK710, the post-update notification setting process is executed in step SK712, the post-confirmation notification setting process is executed in step SK714, or in step SK715. When the clear return notification setting process is executed, the maximum value setting process is executed (step SK716). In the maximum value setting process, the maximum value lottery is performed, and the maximum value of the demo start timer counter 554a is set by setting the numerical value information corresponding to the lottery result of the maximum value lottery in the maximum value counter 579 in the sound-light side RAM 355. Set. The details of the maximum value setting process will be described later.

Like the 77th embodiment, the sound-light side CPU 353 is configured to periodically execute the sound-light side timer interrupt processing (FIG. 284), but the sound-light side startup processing (FIG. 318) is started. At this stage, the generation of the sound light side timer interrupt process (FIG. 284) is prohibited. The state in which the generation of the sound light side timer interrupt processing (FIG. 284) is prohibited is canceled at the timing before the processing of step SK716 is completed and the processing of step SK717 is executed, and the sound light side timer interrupt processing ( The execution of FIG. 284) is permitted. Therefore, after the supply of the operating power to the pachinko machine 10 is started, the maximum value setting process in step SK716 is performed until the maximum value of the demo start timer counter 554a is set in the maximum value counter 579. The optical timer interrupt process (FIG. 284) is not executed. After the maximum value of the demo start timer counter 554a is set in the maximum value counter 579, the interruption of the sound light side timer interrupt processing (FIG. 284) is permitted, and the update of the demo start timer counter 554a is started.

After that, the process proceeds to the sound-light-side residual process in steps SK717 to SK719. As described above, the sound-light side CPU 353 is configured to periodically execute the sound-light side timer interrupt processing (FIG. 284). However, between the sound-light side timer interrupt processing of 1 and the next sound-light side timer interrupt processing. There will be some residual time. This remaining time will vary depending on the processing completion time of the sound light side timer interrupt processing (FIG. 284), but the irregular time is used to repeat the sound light side remaining processing of steps SK717 to SK719. Execute. In this respect, it can be said that the sound-light-side residual process of steps SK717 to SK719 is an aperiodic process that is executed aperiodically.

In the sound-light-side residual processing, first, in step SK717, interrupt prohibition is set in order to prohibit the occurrence of the sound-light-side timer interrupt processing (FIG. 284). In a succeeding step SK718, the random number for random determination is updated. As described above, in the lottery random number update processing in step SK718, the lottery random number information stored in the lottery random number counter 578a in the random number memory 578 is read, and “1” is set to the read lottery random number information. After executing the adding process, the lottery random number counter 578a is overwritten with the lottery random number information after the addition of "1". In the lottery random number update process, when the lottery random number information after the addition of “1” exceeds the maximum value (specifically, “255”), the lottery random number counter 578a is used as the updated lottery random number information. The numerical information of "0" is overwritten. Then, in step SK719, interrupt permission is set to switch from the state in which the generation of the sound-light side timer interrupt processing (FIG. 284) is prohibited to the state in which it is permitted. When the process of step SK719 is executed, the process returns to step SK717, and the sound-light-side residual process of steps SK717 to SK719 is repeated.

As described above, the random number information for lottery in the lottery random number counter 578a is updated by utilizing the irregular remaining time that varies depending on the processing completion time of the sound-light side timer interrupt process (FIG. 284). This prevents the random number information for lottery used in the maximum value lottery from being biased to a specific numerical range, and the result of the maximum value lottery tends to be unintended at the design stage. It is prevented.

As described above, the random number information for lottery stored in the random number counter 578a for lottery is stored and held even when the supply of operating power to the pachinko machine 10 is stopped. The value of the random number counter 578a for lottery is “0” after the supply of the operating power to the pachinko machine 10 is started and before the maximum value setting process is performed in step SK716 of the sound-light side startup process (FIG. 318). "It will not be cleared. As a result, in the plurality of pachinko machines 10, the time from when the supply of the operating power is started to when the maximum value setting process is performed in step SK716 of the sound-light side startup process (FIG. 318) is substantially the same. Even if there is a coincidence, the value of the random number information for lottery used in the maximum value lottery can be set to a different value, except in the case of coincidence. As a result, when the supply of operating power to the plurality of pachinko machines 10 is started at the same time, it is possible to prevent all the results of the maximum value lottery executed first in the plurality of pachinko machines 10 from being the same. ing.

As already described in the 77th embodiment, the setting confirmation process (FIG. 166) and the setting value update process (FIG. 167) use the setting key to switch the setting key insertion portion 68a from the ON state to the OFF state. It ends on the condition that the operation is performed. Since the end timings of the setting confirmation process (FIG. 166) and the set value update process (FIG. 167) vary depending on the timing at which a human operation (operation by the manager of the game hall) is performed, the operating power of the pachinko machine 10 is reduced. During the period from the start of the supply until the sound-light side CPU 353 receives the return command for confirmation or the return command for update, the sound-light side CPU 353 normally operates after the supply of the operating power to the pachinko machine 10 is started. The period is different from the period until the return command or the return command at the time of clear is received. In the present embodiment, the sound-light side timer interrupt process (FIG. 7) is performed after the process (the process of steps SK702 to SK715) performed based on the sound-light side CPU 353 receiving one of the return commands from the main-side CPU 63 is completed. 284) interrupt is permitted and the demo start timer counter 554a is started to be updated. Therefore, even if the supply of the operating power to the plurality of pachinko machines 10 is started at the same time, the timing of starting the update of the demonstration start timer counter 554a in the plurality of pachinko machines 10 is the "setting confirmation operation". Also, the timing varies depending on whether or not there is a “setting change operation”.

As already described, the demonstration effect is started at the timing when the value of the timer counter 554a for starting the demonstration reaches the maximum value in the start waiting state. In the configuration in which the value of the demo start timer counter 554a periodically reaches the maximum value after the update of the demo start timer counter 554a is started, the supply of operating power to the plurality of pachinko machines 10 is simultaneously started. In this case, in the pachinko machine 10 for which the “setting confirmation operation” or the “setting change operation” was performed when the supply of the operating power was started, and the pachinko machine 10 for which the “setting confirmation operation” and the “setting change operation” were not performed. The timing at which the value of the demo start timer counter 554a reaches the maximum value deviates, and the timing at which the demonstration effect starts in the start waiting state deviates. Therefore, in the configuration, the pachinko machine 10 for which the “setting confirmation operation” or the “setting change operation” has been performed may be easily identified based on the start timing of the demonstration effect.

On the other hand, in the present embodiment, the maximum value of the timer counter 554a for starting a demo is irregularly updated, regardless of the presence or absence of the "setting confirmation operation" and the "setting change operation" at the start of the supply of the operating power. Instead, it is a configuration that intentionally creates a situation in which the start timing of the demonstration effect is shifted in the plurality of pachinko machines 10. Accordingly, it is possible to prevent the pachinko machine 10 for which the “setting confirmation operation” or the “setting change operation” is performed from being easily identified from among the plurality of pachinko machines 10 based on the start timing of the demonstration effect. You can

Next, the maximum value setting process executed by the sound-light side CPU 353 will be described with reference to the flowchart of FIG. 319(a). The maximum value setting process is executed in step SK716 of the sound-light side start-up process (FIG. 318) and step SK905 of the demo start timer counter 554a described later (FIG. 320).

In the maximum value setting process, the maximum value lottery table used for the maximum value lottery is read from the sound-light side ROM 354 to the sound-light side RAM 355 (step SK801). FIG. 319( b) is an explanatory diagram for explaining the maximum value lottery table 581. As shown in FIG. 319(b), in the maximum value lottery table 581, as the numerical value information set as the maximum value of the demonstration start timer counter 554a in the maximum value counter 579 in the sound-light side RAM 355 after the maximum value lottery. “2599”, “2999”, “3399” and “3799” are set.

In the maximum value lottery, when the lottery random number information read from the lottery random number counter 578a is in the numerical range of “0” to “63”, “2599” is set in the maximum value counter 579, and the lottery random number information. Is within the numerical range of “64” to “127”, the maximum value counter 579 is set to “2999”, and when the lottery random number information is within the numerical range of “128” to “191”, the maximum When the value counter 579 is set to “3399” and the random number information for lottery is in the numerical range of “192” to “255”, “3799” is set to the maximum value counter 579. In the maximum value lottery, the probability that the maximum value counter 579 is set to "2599" after the maximum value lottery, the probability that the maximum value counter 579 is set to "2999", and the maximum value counter 579 is set to "3399" The probability and the probability that the maximum value counter 579 is set to “3799” are the same as “1/4”.

Returning to the description of the maximum value setting process (FIG. 319(a)), the maximum value lottery table 581 is read in step SK801, and the lottery random number information stored in the lottery random number counter 578a in the random number memory 578 is loaded. Read out (step SK802). After that, by comparing the random number information for lottery read in step SK802 with the maximum value lottery table 581 read in step SK801, the numerical information to be set in the maximum value counter 579 as the maximum value of the timer counter 554a for starting the demonstration is specified. Yes (step SK803). Then, the specified numerical value information is set in the maximum value counter 579 (step SK804), and the maximum value setting process is ended. As a result, the maximum value of the timer counter 554a for starting the demonstration is updated.

As already described in the 77th embodiment, in the start waiting effect process (FIG. 285), when the start waiting effect flag in the sound-light side RAM 355 is set to “1” (step SI706: YES), That is, in the case where the start waiting effect (either the demonstration effect or the waiting symbol display) is performed on the symbol display device 41, the value of the timer counter 554a for starting the demonstration is "1999" (step SI710: YES). Then, the standby symbol display start setting process is executed (step SI711). When the value of the timer counter 554a for starting the demonstration is the maximum value (step SI712: YES), the start setting process of the demonstration effect is executed (step SI709). In the present embodiment, when "2599" is set as the maximum value of the timer counter 554a for starting the demonstration, the demonstration effect is executed for 10 seconds, and then the standby symbol display is executed for 3 seconds. When "2999" is set as the maximum value of the timer counter 554a for demonstration start, after the demonstration effect is executed for 10 seconds, the standby symbol display is executed for 5 seconds. When "3399" is set as the maximum value of the timer counter 554a for demonstration start, after the demonstration effect is executed for 10 seconds, the standby symbol display is executed for 7 seconds. When "3799" is set as the maximum value of the timer counter 554a for demonstration start, after the demonstration effect is executed for 10 seconds, the standby symbol display is executed for 9 seconds.

Next, the updating process of the demonstration start timer counter 554a executed by the sound-light side CPU 353 will be described with reference to the flowchart of FIG. Note that the demo start timer counter 554a is updated in step SI601 of the sound-light side timer interrupt process (FIG. 284).

In the process of updating the demo start timer counter 554a, the value of the demo start timer counter 554a in the sound-light side RAM 355 is incremented by 1 (step SK901). After that, the maximum value of the demonstration start timer counter 554a set in the maximum value counter 579 is grasped (step SK902). Then, it is determined whether or not the value of the demo start timer counter 554a after adding 1 in step SK901 exceeds the maximum value grasped in step SK902 (step SK903).

If it is determined in step SK903 that the value of the demo start timer counter 554a does not exceed the maximum value, the updating process of the demo start timer counter 554a is ended. On the other hand, if it is determined in step SK903 that the value of the demo start timer counter 554a exceeds the maximum value, the value of the demo start timer counter 554a is cleared to "0" (step SK904). Then, the maximum value setting process already described with reference to FIG. 319(a) is executed (step SK905), and the updating process of the timer counter 554a for starting the demo is ended. By executing the maximum value setting process in step SK905, the maximum value of the demonstration start timer counter 554a is updated in a manner corresponding to the lottery result in the maximum value lottery.

According to this embodiment described in detail above, the following excellent effects are exhibited.

The demonstration effect is started at the timing when the value of the timer timer 554a for starting a demo reaches the maximum value in the start waiting state. After the value of the demo start timer counter 554a reaches the maximum value, the maximum value lottery is carried out at the timing when "0" is cleared, and the demo start timer counter 554a is displayed in a manner corresponding to the lottery result in the maximum value lottery. Maximum value is updated. As a result, the timing at which the value of the demonstration start timer counter 554a reaches the maximum value is regarded as irregular timing, and the demonstration effect can be started at irregular timing in the start waiting state. Further, when the supply of the operating power to the plurality of pachinko machines 10 is started at the same time, regardless of the presence or absence of the “setting confirmation operation” and the “setting change operation” at the start of the supply of the operating power, intentionally, It is possible to create a situation in which the start timing of the demonstration effect is deviated in the plurality of pachinko machines 10. Accordingly, it is possible to prevent the pachinko machine 10 for which the “setting confirmation operation” or the “setting change operation” is performed from being easily identified from among the plurality of pachinko machines 10 based on the start timing of the demonstration effect. You can

The random number information for lottery used in the maximum value lottery is updated by using the irregular remaining time that fluctuates according to the processing completion time of the sound-light side timer interrupt processing (FIG. 284). This prevents the random number information for lottery used in the maximum value lottery from being biased to a specific numerical range, and the result of the maximum value lottery tends to be unintended at the design stage. It is prevented.

The processing completion time of the sound and light side timer interrupt processing (FIG. 284) varies depending on the operation mode of the firing operation device 28 by the player, the game ball entering mode, and the like. The lottery random number information stored in the lottery random number counter 578a is stored and held even when the supply of operating power to the pachinko machine 10 is stopped. Therefore, it is assumed that the supply of the operating power to the plurality of pachinko machines 10 is started at the same time, and the time from the start of the supply of the operating power to the first maximum value lottery is approximately the same time. Also, the value of the random number information for lottery used in the maximum value lottery in the plurality of pachinko machines 10 can be made different except for the case of coincidence. As a result, it is possible for the plurality of pachinko machines 10 to have different values for the random number for lottery used in the maximum value lottery, and the pachinko machines 10 are executed immediately after the supply of operating power is started. It is prevented that the results of the maximum value lottery performed are all the same.

In addition, in the configuration for making the random number information for lottery used for the maximum value lottery in the plurality of pachinko machines 10 different values, the update of the random number information for lottery is performed aperiodically in the sound-light-side residual process. The configuration is not limited. For example, in the sound/light side timer interrupt processing (FIG. 284), the random number update process for the lottery (step SK718 of the sound/light side startup processing (FIG. 318)) is executed on condition that the start waiting state is satisfied. May be The start timing and the end timing of the start waiting state vary depending on the manner of operation of the firing operation device 28 by the player, the manner of entering a game ball, and the like. Therefore, even when the supply of the operating power to the plurality of pachinko machines 10 is started at the same time, the lottery random number updating process (step SK718 of the sound-light side start-up process (FIG. 318)) is performed thereafter. The number of times of execution varies depending on the manner of operation of the firing operation device 28 by the player, the manner of entering a game ball, and the like. Thereby, the random number information for lottery used in the maximum value lottery in the plurality of pachinko machines 10 can have different values.

Further, the configuration for acquiring the lottery numerical value information that is not biased to the specific numerical value range immediately after the supply of the operating power to the pachinko machine 10 is started is because the information is stored and held in the sound emission control board 351. The configuration is not limited to the configuration in which the random number memory 578 to which the backup power is supplied is provided. For example, as in the 79th embodiment, the main CPU 63 sends a return command (a normal return command, an update return command, a confirmation return command, or a clear return command) to the sound/light CPU 353. ), random number information for lottery may be set. Specifically, as in the 79th embodiment, when the main CPU 63 determines in step SB105 of the main process (FIG. 165) that the checksum is normal, the work area 221 for specific control is determined. Numerical value information stored in the random number initial value counter CINI is set in the transmission random number storage counter 556 (FIG. 290). As already described in the 79th embodiment, a structure in which backup power for storing and holding information is supplied to the work area 221 for specific control in a state where the supply of operating power to the pachinko machine 10 is stopped. Immediately after the supply of operating power to the pachinko machine 10 is started, the random number initial value counter CINI stores numerical value information that is not biased to a specific numerical value range. When transmitting any of the return commands to the sound-light side CPU 353, the main CPU 63 sets the numerical information set in the transmission random number storage counter 556 as the random number information for lottery in the return command. In this way, the sound-light side CPU 353 receives the random number information for lottery from which the bias toward the specific numerical range is prevented from being supplied from the main CPU 63, whereby backup power is supplied to the sound emission control board 351. It is possible to acquire the lottery numerical value information that is not biased to a specific numerical value range immediately after the supply of the operating power to the pachinko machine 10 is started without providing a storage area.

Further, each time the value of the demo start timer counter 554a reaches the maximum value, a maximum value lottery is performed to set the maximum value of the demo start timer counter 554a, instead of supplying the operating power to the pachinko machine 10. An initial value lottery may be performed to determine the numerical value information to be set as the initial value in the demo start timer counter 554a from among a plurality of numerical value information at the start. Specifically, the maximum value of the timer counter 554a for starting the demonstration is fixed to "2999". The initial value lottery is executed when the sound/light side CPU 353 receives from the main side CPU 63 any one of a normal return command, an update return command, a check return command, and a clear return command. After the supply of the operating power to the pachinko machine 10 is started, the initial value lottery is executed only once before the supply of the operating power is stopped. The initial value lottery is performed using the lottery random number information stored in the lottery random number counter 578a already described in the 88th embodiment. As described above in the 88th embodiment, the random number information for lottery stored in the random number counter for lottery 578a is any numerical information of “0” to “255”, and the operating power to the pachinko machine 10. The random number information for lottery stored in the random number counter for lottery 578a immediately after the start of the supply is numerical value information that is not biased to a specific numerical range.

The sound-light side ROM 354 stores an initial value lottery table used for initial value lottery, and a plurality of types (specifically, four types) of initial values are set in the initial value lottery table. In the initial value lottery, when the random number for lottery stored in the random number for lottery 578a is in the numerical range of "0" to "63", "0" is set as the initial value in the timer counter 554a for start of demonstration. If the random number information for lottery is in the numerical range of “64” to “127”, “999” is set as the initial value in the timer counter 554a for starting demo, and the random number information for lottery is “128” to “191”. "1999" is set as the initial value in the demo start timer counter 554a in the numerical range of "", and the demo start timer counter is in the case where the random number information for lottery is in the numerical range of "192" to "255". “2998” is set to 554a as an initial value. In the initial value lottery, the probability that the demo start timer counter 554a is set to "0" as an initial value, the probability that the demo start timer counter 554a is set to "999", and the demo start timer counter 554a is set to "1999" And the probability that the demo start timer counter 554a is set to "2998" are "1/4" and are the same.

In the initial value lottery, if the initial value of the timer counter 554a for starting the demo is "0", 15 seconds after the interruption of the sound light side timer interruption process (Fig. 284) is permitted, the symbol display device 41 When the demonstration effect is started and the initial value of the timer counter 554a for starting the demonstration is "999", the demonstration effect is started 10 seconds after the interruption of the sound light side timer interruption process (Fig. 284) is permitted. When the initial value of the demonstration start timer counter 554a is "1999", the demonstration effect is started 5 seconds after the interruption of the sound-light side timer interruption process (FIG. 284) is permitted. Further, in the initial value lottery, when the initial value of the timer counter 554a for starting the demonstration is "2998", the sound to be performed first after the interruption of the sound light side timer interruption processing (Fig. 284) is permitted. In step SI601 of the light side timer interrupt process (FIG. 284), the value of the demo start timer counter 554a reaches the maximum value (specifically, 2999). In this case, the demonstration effect is started by executing the start waiting effect process in step SI621 of the sound-light timer interrupt process (FIG. 284) in the processing time. That is, the demonstration effect is started on the symbol display device 41 immediately after the interruption of the sound light side timer interruption process (FIG. 284) is permitted.

By preventing the random number information for lottery in the random number for lottery 578a from being biased to a specific numerical range, it is possible to prevent a specific tendency from being generated in the result of the initial value lottery. In addition, as already described in the 88th embodiment, the lottery numerical value information stored in the lottery random number counter 578a is not cleared to “0” at the start of supplying the operating power to the pachinko machine 10. Even if the supply of operating power to the pachinko machines 10 is started at the same time, the random number information for lottery used in the initial value lottery in the plurality of pachinko machines 10 has different values except when they coincide by chance. Therefore, the initial value lottery is performed only once when the supply of the operating power to the pachinko machine 10 is started, and the numerical information corresponding to the lottery result of the initial value lottery is set as the initial value of the demonstration start timer counter 554a. Even when the supply of the operating power to the plurality of pachinko machines 10 is simultaneously started, the timing at which the value of the demo start timer counter 554a reaches the maximum value in the plurality of pachinko machines 10 is the lottery of the initial value lottery. The timing can be different depending on the result, and the timing at which the demonstration effect is started in the start waiting state can be different. The situation in which the start timing of the demonstration effect is shifted in the plurality of pachinko machines 10 is intentionally created regardless of the presence or absence of the “setting confirmation operation” and the “setting change operation” at the time of starting the supply of the operating power. As a result, it is possible to prevent the pachinko machine 10 for which the “setting confirmation operation”, the “setting change operation”, or the “RAM clear operation” has been performed based on the start timing of the demonstration effect from being easily identified. it can.

<Embodiment 89>
In this embodiment, the display content on the display device for notifying the management result of the game history is different from that in the 35th embodiment. The configuration different from that of the 35th embodiment will be described below. The description of the same configuration as the thirty-fifth embodiment is basically omitted.

FIG. 321 is a front view of main controller 60 in the present embodiment.

As shown in FIG. 321, the main controller 60 in the present embodiment includes a first notification display device 591, a first notification display device 591, a first notification display device 591 in place of the first to fourth notification display devices 201 to 204 in the thirty-fifth embodiment. A second notification display device 592, a third notification display device 593, a fourth notification display device 594, and a fifth notification display device 595 are provided. The first to fifth notification display devices 591 to 595 are provided side by side on the element mounting surface of the main control board 61.

Each of the first to fifth notification display devices 591 to 595 is a segment display in which a plurality of LED display segments are arranged, but the display device is not limited to this, and a single multi-color emission type light emission is provided. It may be a body, a liquid crystal display device, or an organic EL display. Eight display segments are arranged on the first notification display device 591, and seven display segments are arranged on the second to fifth notification display devices 592 to 595. All of the first to fifth notification display devices 591 to 595 are installed so that their display surfaces face the direction in which the element mounting surface of the main control board 61 faces, and the opposing wall portion 60b of the board box 60a allows Is covered. In this case, since the substrate box 60a is formed transparent, the display surfaces of the first to fifth notification display devices 591 to 595 accommodated in the substrate box 60a are visually observed from the outside of the substrate box 60a. It becomes possible. Further, the main controller 60 is mounted on the back surface of the resin base 21 so that the facing wall portion 60b facing the element mounting surface of the main control board 61 in the board box 60a faces the back of the pachinko machine 10, so that the gaming machine. When the main body 12 is opened to the front of the pachinko machine 10 with respect to the outer frame 11 and the back surface of the resin base 21 is exposed to the front of the pachinko machine 10, the first to fifth notification display devices 591 are provided through the facing wall portion 60b. It becomes possible to visually observe the display surfaces of ~595. The display contents on the first to fifth notification display devices 591 to 595 will be described later.

FIG. 322 is an explanatory diagram for explaining various areas of the work area 223 for non-specific control used for managing the game history.

As shown in FIG. 322, the work area 223 for non-specific control is provided with an incoming ball number counter area 596 instead of the normal counter area 231 in the thirty-fifth embodiment. A general winning counter 596a, a special electric winning counter 596b, a first operation counter 596c, a second operation counter 596d, and an out counter 596e are provided in the incoming ball number counter area 596. In various counters 596a to 596e in the incoming ball number counter area 596, the incoming ball numbers of the game balls in all the gaming states are measured without distinguishing the gaming states. Specifically, the all game state is a game state that is neither the open/close execution mode nor the high frequency support mode, the game state that is the open/close execution mode, and the game state that is the high frequency support mode. The general winning counter 596a is a counter for counting the number of game balls entered into the general winning opening 31 from a predetermined measurement start timing. The special electric prize winning counter 596b is a counter for counting the number of game balls entered into the special electric prize winning device 32 from a predetermined measurement start timing. The first operation counter 596c is a counter for measuring the number of game balls entering the first operation port 33 from a predetermined measurement start trigger. The second operation counter 596d is a counter for measuring the number of game balls entering the second operation port 34 from a predetermined measurement start trigger. The out counter 596e is a counter for measuring the number of game balls entering the out port 24a from a predetermined measurement start trigger.

The various counters 596a to 596e in the incoming ball number counter area 596 are for measuring the number of game balls entered in the targeted ball portions 24a and 31 to 34 in a situation where the front door frame 14 is in the closed state. Used for. Specifically, in the above-mentioned all game states, when one game ball enters the general winning opening 31, the value of the general prize counter 596a is incremented by 1, and one special game ball 32 in the special prize winning device 32. When the player enters, the value of the special electric prize winning counter 596b is incremented by 1, and when one game ball is entered into the first operating port 33, the value of the first operating counter 596c is incremented by 1, and the second When one game ball enters the operating port 34, the value of the second operation counter 596d is incremented by 1, and when one game ball enters the out port 24a, the value of the out counter 596e is increased. 1 is added.

In addition, the situation where the front door frame 14 is in the open state is out of the measurement target because the game ball enters the ball entry portions 24a, 31 to 34 with the front door frame 14 open. This is because the number of entered balls in the case of being excluded is excluded from the measurement target. However, the present invention is not limited to this, and a configuration in which the front door frame 14 is in the open state may be a measurement target similarly to the situation in which the front door frame 14 is in the closed state.

In the present embodiment, the main CPU 63 calculates a plurality of types of payout rates. The payout rate is the ratio of the total payout number to the total number of game balls discharged from the game area PA of the pachinko machine 10 in the entire gaming state. When the values of the various counters 596a to 596e in the incoming ball number counter area 596 are K101 to K105, the payout rate is as follows.
-Dot rate: total payout number of game balls (K101 x "number of prize balls for winning in general prize hole 31" + K102 x "number of prize balls for winning in special electric prize winning device 32" + K103 x "first operating port 33" Ratio of the number of prize balls for winning the prize”+K104דthe number of prize balls for winning the second actuating port 34”)/the total number of game balls discharged from the game area PA (K101+K102+K103+K104+K105).

In the present embodiment, the main CPU 63 uses the current payout rate, the payout rate in the unit calculation period, the payout rate in the entire unit calculation period for the last four times, the payout rate in the first calculation period, and the latest. The payout rate in the entire unit calculation period for 10 times and the payout rate in the second calculation period are calculated.

The current payout rate is a payout rate calculated based on the values stored in the various counters 596a to 596e in the current incoming ball number counter area 596. The current payout rate is the total payout number of the above-mentioned gaming balls (K101 x "number of prize balls for winning in the general winning opening 31" + K102 x "number of prize balls for winning in the special electric prize winning device 32" + K103 x "No. 1) The number of prize balls for winning in the operating port 33"+K104 x "the number of prize balls for winning in the second operating port 34") is divided by the total number of game balls discharged from the game area PA (K101+K102+K103+K104+K105) to obtain 100. Calculated as doubled percentage data. The current payout rate is 100% when the total payout number of game balls and the total number of game balls discharged from the game area PA are the same, and the total payout number of game balls is discharged from the game area PA. If the total number of game balls is greater than 100%, the total payout number of game balls is less than 100% if the total number of game balls discharged from the game area PA is less than 100%. Become. Information on the current payout rate (hereinafter, also referred to as current payout rate data) is stored as numerical information in the range of "0%" to "999%". The current payout rate is 3-digit numerical information in decimal notation.

As already described in the first embodiment, when one game ball enters the first operating port 33, or one game ball enters the second operating port 34. In this case, one prize ball is paid out, and when one game ball is thrown into the general winning opening 31, ten prize balls are paid out, and the special electric prize winning device When one game ball enters 32, the payout of 15 prize balls is executed. When the current payout rate exceeds “999%”, the current payout rate is stored as “999%”. The number of prize balls is arbitrary, and for example, the number of prize balls may be smaller in the second operating port 34 than in the first operating port 33, and the second operating port 34 may be the first operating port. The number of prize balls may be larger than 33.

The unit calculation period is a period until the number of gaming balls discharged from the gaming area PA of the pachinko machine 10 reaches the unit reference number (specifically, 6000) in all gaming states. When one unit calculation period ends, the next unit calculation period starts. The values of the various counters 596a to 596e in the incoming ball number counter area 596 are cleared to "0" every time the unit calculation period ends. In the pachinko machine 10, a maximum of 100 game balls are shot in one minute, so the unit reference number of 6000 is the maximum number of shots in one hour. When the number of game balls discharged from the game area PA reaches the maximum number of shots in one hour, one unit calculation period ends and a new unit calculation period starts. The unit reference number is not limited to 6000, and may be any number as long as it is a plural number, and may be set to a number less than 6000 or more than 6000. Good.

In the present embodiment, each time the unit calculation period ends, the final payout rate in the ended unit calculation period (hereinafter, also referred to as the payout rate in the unit calculation period) is calculated. The payout rate in the unit calculation period is calculated based on the values stored in the various counters 596a to 596e in the incoming ball number counter area 596 at the end of the unit calculation period. The payout rate in the unit calculation period is, like the current payout rate, the total number of payouts of the above-mentioned game balls (K101דthe number of prize balls for winning in the general winning opening 31”+K102דto the special electric winning device 32”). Number of prize balls for winning the prize”+K103דnumber of prize balls for winning the first operating port 33”+K104דnumber of prize balls for winning the second operating port 34”) It is calculated as a percentage data which is divided by the total number of spheres (K101+K102+K103+K104+K105) and multiplied by 100. The information on the payout rate in the unit calculation period (hereinafter, also referred to as the payout rate data in the unit calculation period) is stored as numerical information in the range of “0%” to “999%”. The payout rate in the unit calculation period is 3-digit numerical information in decimal notation.

The payout rate in the entire unit calculation period for the latest four times is calculated by dividing the total value of the four payout rates in each unit calculation period for the latest four times by “4”. The payout rate information in the entire unit calculation period for the latest four times (hereinafter, also referred to as the payout rate data in the entire unit calculation period for the latest four times) is numerical information in the range of "0%" to "999%". Is stored as The payout rate in the entire unit calculation period for the last four times is 3-digit numerical information in decimal notation.

The first calculation period is a period for four times of the unit calculation period, and the total number of game balls discharged from the game area PA of the pachinko machine 10 is the unit reference number (specifically, 6000 pieces) in all game states. It is a period until it reaches 24000, which is four times as large as that in FIG. When the number of game balls discharged from the game area PA reaches the maximum number of shots in four hours, one first calculation period ends and a new first calculation period starts. Each time the unit calculation period ends four times, one first calculation period ends.

The payout rate in the first calculation period is calculated by dividing the total value of the four payout rates in each of the four unit calculation periods included in the first calculation period by “4”. The information of the payout rate in the first calculation period (hereinafter, also referred to as the payout rate data in the first calculation period) is “0%” to “999%”, like the information of the payout rate in the unit calculation period. It is stored as numerical information in the range. The payout rate in the first calculation period is 3-digit numerical information in decimal notation.

The payout rate in the entire unit calculation period for the latest 10 times is calculated by dividing the total value of the 10 payout rates in each unit calculation period for the latest 10 times by “10”. The information on the payout rate in the entire unit calculation period for the last 10 times (hereinafter, also referred to as the payout rate data in the entire unit calculation period for the latest 10 times) is numerical information in the range of "0%" to "999%". Is stored as The payout rate in the entire unit calculation period for the last 10 times is 3-digit numerical information in decimal notation.

The second calculation period is a period of 10 times of the unit calculation period, and the total number of game balls discharged from the game area PA of the pachinko machine 10 is the unit reference number (specifically, 6000 pieces) in all game states. It is a period until it reaches 60000, which is 10 times as large as that in FIG. When the number of game balls discharged from the game area PA reaches the maximum number of shots in 10 hours, one second calculation period ends and a new second calculation period starts. Each time the unit calculation period ends 10 times, one second calculation period ends.

The payout rate in the second calculation period is calculated by dividing the total value of the 10 payout rates in the 10 unit calculation periods included in the second calculation period by “10”. The information of the payout rate in the second calculation period (hereinafter, also referred to as the payout rate data in the second calculation period) is “0%” to “999%”, like the information of the payout rate in the unit calculation period. It is stored as numerical information in the range. The payout rate in the second calculation period is 3-digit numerical information in decimal notation.

In the first to fifth notification display devices 591 to 595, the payout rate in the entire unit calculation period for the latest four times, the payout rate in the first calculation period, the payout rate in the entire unit calculation period for the latest ten times, and The payout rate in the second calculation period is displayed. On the first to fifth notification display devices 591 to 595, three-digit numbers (any one of "000" to "999") corresponding to these payout rates are displayed. The details of display contents on the first to fifth notification display devices 591 to 595 will be described later.

In the pachinko machine 10, a numerical value of 41% to 149% as the first normal range, which is a normal range of the payout rate in the entire unit calculation period for the latest four times and the normal payout rate in the first calculation period, which is assumed at the design stage. The range is set. In addition, a numerical range of 51% to 133% is set as the second normal range which is a normal range of the payout rate in the entire unit calculation period for the last 10 times assumed in the design stage and the payout rate in the second calculation period. Has been done. In the first to fifth notification display devices 591 to 595, the ball output rate in the entire unit calculation period for the latest four times is less than 41% which is the lower limit of the first normal range, and the first calculation period. In the situation where the payout rate is less than 41% which is the lower limit of the first normal range, the payout rate in the entire unit calculation period for the last 10 times is less than 51% which is the lower limit of the second normal range. By making it possible to understand that there is a situation where the payout rate in the second calculation period is below the lower limit of 51% in the second normal range, it is possible to inform the manager of the game hall. It is possible to give an opportunity to perform maintenance for adjusting the state of the nails 24b scolded on the game board 24 in the pachinko machine 10. In addition, in the first to fifth notification display devices 591 to 595, the payout rate in the entire unit calculation period for the last four times is higher than the upper limit of the first normal range of 149%. The payout rate in the calculation period is higher than the upper limit of 149% in the first normal range, and the payout rate in the entire unit calculation period for the last 10 times is 133%, which is the upper limit of the second normal range. By making it possible to understand that the situation is higher, or that the payout rate in the second calculation period is higher than the upper limit of the second normal range of 133%, it is possible for the manager of the game hall to know. On the other hand, it is possible to give an opportunity to confirm whether or not there is an action that illegally raises the total payout number of gaming balls.

On the first to fifth notification display devices 591 to 595, the payout rate in the entire unit calculation period for the latest four times, the payout rate in the first calculation period, and the latest 10 in the numerical range of “000” to “999”. Due to the configuration in which the payout rate in the entire unit calculation period for each batch and the payout rate in the second calculation period are displayed, these payout rates are within the normal range (first normal range or second normal range). If it is below the lower limit (41% in the first normal range, 51% in the second normal range), not only whether there is an abnormality in which the payout rate is below the lower limit of the normal range, but also the degree of the abnormality is grasped. It is possible. Specifically, it is possible to understand that the lower the ball output rate is, the more serious the anomaly is and the need for prompt response. In addition, when these ball output rates exceed the upper limit of the normal range (149% in the first normal range and 133% in the second normal range), these ball output rates exceed the upper limit of the normal range. It is possible to understand not only the presence or absence but also the degree of the abnormality. Specifically, it is possible to understand that the higher the ball output rate is, the more serious the anomaly is and the need for prompt action.

As shown in FIG. 322, a calculation start flag 597 is provided in the work area 223 for non-specific control. The calculation start flag 597 has a value of “0” when the supply of operating power to the pachinko machine 10 is started for the first time after the pachinko machine 10 is manufactured. The value of the calculation start flag 597 also becomes “0” when the work area 223 for non-specific control including the calculation start flag 597 is cleared to “0” and initialized. In the calculation start flag 597, the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) in all game states is a calculation start reference number (specifically, 300). "1" is set when the number becomes "1". When the calculation start flag 597 is set to "1", the values of the various counters 596a to 596e in the incoming ball number counter area 596 are cleared to "0" and the first unit calculation period, the first calculation period, and the second calculation period. Is started.

When the pachinko machine 10 is shipped, for example, an operation check of the pachinko machine 10 may be performed before shipping, and in that case, a trial hit of a game ball may be performed. The payout rate in such a situation can be a value different from that in a situation where a normal game is played. Therefore, when the calculation start flag 597 is not set to "1", the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) is the unit reference number (specifically, The number of counters 596a to 596e in the incoming ball number counter area 596 is cleared to “0” once when the number of calculation start reference numbers (300) is less than 6000). After the shipment of 10, it is possible to reduce the influence of the above operation check on the payout rate in the situation where a normal game is played. Note that the calculation start reference number is not limited to 300, and may be any number as long as it is a plurality, and may be set to a number less than 300 or more than 300. Good.

As shown in FIG. 322, the work area 223 for non-specific control is provided with a calculation area 598, a current payout rate area 599, a first management buffer 601, and a second management buffer 602.

The calculation area 598 includes various payout rates (current payout rate, payout rate in the unit calculation period, payout rate in the entire unit calculation period for the last four times, payout rate in the first calculation period, and the most recent ten times. This is a storage area used to calculate the payout rate in the entire unit calculation period and the payout rate in the second calculation period. The calculation area 598 has a storage capacity of 2 bytes in which numerical information in the numerical range of “0” to “65535” can be set.

The current payout rate area 599 is a counter for storing the above-mentioned current payout rate data. The current payout rate area 599 has a storage capacity of 10 bits so that the current payout rate data (numerical information of any of “0” to “999”) can be stored.

The first management buffer 601 is a ring buffer that stores information for calculating the payout rate in the first calculation period (specifically, four payout rate data in each of the latest four unit calculation periods). is there. The first management buffer 601 is provided with 0th storage area 601a to 3rd storage area 601d as storage areas for storing the payout rate data in the unit calculation period. All of these storage areas 601a to 601d have the same storage capacity, and specifically, it is possible to store the payout rate data (numerical information of any one of "0" to "999") in the unit calculation period. Therefore, the capacity is 10 bits.

The data amount of the information on the final total payout number in the unit calculation period is larger than the data amount of the payout rate data in the unit calculation period. Therefore, the first management buffer 601 stores information on the four total payout numbers in the last four unit calculation periods, and the total value of the four total payout numbers is the unit reference number (specifically, 6000). If the configuration is such that the payout rate in the entire unit calculation period for the latest four times is calculated by dividing by “24000”, which is four times the number of pieces), the storage capacity of each storage area 601a to 601d of the first management buffer 601 is calculated. There is a need to increase it. On the other hand, in the present embodiment, the four payout rate data in the latest four unit calculation periods are stored in the first management buffer 601, and the total value of the four payout rates is “4”. This is a configuration in which the payout rate in the first calculation period is calculated by dividing. This makes it possible to reduce the storage capacity of each of the storage areas 601a to 601d of the first management buffer 601.

A first write pointer 603 is provided in the work area 223 for non-specific control. The first write pointer 603 is a counter for allowing the main CPU 63 to grasp the storage areas 601a to 601d to be the current write destination among the four storage areas 601a to 601d of the first management buffer 601. The first write pointer 603 is a loop counter in which 1 is added to the previous value each time it is updated, and after reaching the maximum value (specifically, “3”), it returns to “0”. The value of “n” of the first write pointer 603 (n is any integer from 0 to 3) corresponds to the state where the write destination is the nth storage area 601a to 601d. For example, the value "0" of the first write pointer 603 corresponds to the state where the write destination is the 0th storage area 601a, and the value "2" of the first write pointer 603 is the write destination of the second storage area 601a. This corresponds to the state of the area 601c.

Every time the unit calculation period ends, the main CPU 63 calculates the final payout rate in the unit calculation period ended this time based on the values stored in the various counters 596a to 596e of the incoming ball number counter area 596. To do. Then, the calculated payout rate information is written in the storage areas 601a to 601d of the first management buffer 601 corresponding to the value of the first write pointer 603. The value of the first write pointer 603 is incremented by 1 each time the information of the payout rate is written in the first management buffer 601, and the value after the increment of 1 exceeds the maximum value (specifically, “3”). Is cleared to "0". Therefore, in the 0th to 3rd storage areas 601a to 601d in the first management buffer 601, four ball output rate data in each of the latest four unit calculation periods are set.

The value of the first write pointer 603 becomes “0” by making one round by writing the payout rate data in the unit calculation period four times in the first management buffer 601. The main-side CPU 63 recognizes that the first calculation period has ended based on the value of the first write pointer 603 making one round to become “0”. Therefore, a main counter for grasping the end timing of the first calculation period is compared with a configuration in which a dedicated counter for grasping the end timing of the first calculation period is provided separately from the first write pointer 603. The storage capacity of the side RAM 65 is reduced.

The second management buffer 602 is a ring buffer that stores information for calculating the payout rate in the second calculation period (specifically, 10 payout rate data in each of the latest 10 unit calculation periods). is there. The second management buffer 602 is provided with 0th storage area 602a to 9th storage area 602j as storage areas for storing the payout rate data in the unit calculation period. All of these storage areas 602a to 602j have the same storage capacity, and specifically, it is possible to store payout rate data (numerical information of any one of "0" to "999") in the unit calculation period. Therefore, the capacity is 10 bits.

The data amount of the information on the final total payout number in the unit calculation period is larger than the data amount of the payout rate data in the unit calculation period. Therefore, the information of the total payout number of 10 pieces in the unit calculation period for the last 10 times is stored in the second management buffer 602, and the total value of the total payout number of 10 pieces is 10 times the unit reference number “60000”. If the configuration is such that the payout rate in the unit calculation period for the last 10 times is calculated by dividing by “”, it becomes necessary to increase the storage capacity of each storage area 602a to 602j of the second management buffer 602. On the other hand, in the present embodiment, the second management buffer 602 stores information on the 10-ball-out rate in the last 10 unit calculation periods, and the total value of the 10-ball-out rate is “10”. This is a configuration in which the payout rate in the second calculation period is calculated by dividing. This makes it possible to reduce the storage capacity of each of the storage areas 602a to 602j of the second management buffer 602.

A second write pointer 604 is provided in the work area 223 for non-specific control. The second write pointer 604 is a counter that enables the main CPU 63 to grasp the storage areas 602a to 602j that are the write destinations this time among the 10 storage areas 602a to 602j of the second management buffer 602. The second write pointer 604 is a loop counter in which 1 is added to the previous value each time it is updated, and the maximum value (specifically, “9”) is reached and then returned to “0”. The value of “m” of the second write pointer 604 (m is an integer from 0 to 9) corresponds to the state where the write destination is the mth storage area 602a to 602j. For example, the value of “0” of the second write pointer 604 corresponds to the state where the write destination is the 0th storage area 602a, and the value of “2” of the second write pointer 604 is the write destination of the second storage area 602a. This corresponds to the state of the area 602c.

Every time the unit calculation period ends, the main CPU 63 calculates the final payout rate in the unit calculation period ended this time based on the values stored in the various counters 596a to 596e of the incoming ball number counter area 596. To do. Then, the calculated payout rate information is written in the storage areas 602a to 602j of the second management buffer 602 corresponding to the value of the second write pointer 604. The value of the second write pointer 604 is incremented by 1 each time the information on the payout rate is written in the second management buffer 602, and the value after the increment of 1 exceeds the maximum value (specifically, “9”). Is cleared to "0". Therefore, ten payout rate data in each of the latest ten unit calculation periods is set in the 0th to ninth storage areas 602a to 602j in the second management buffer 602.

The value of the second write pointer 604 becomes “0” after one round when the ball output rate data in the unit calculation period is written 10 times in the second management buffer 602. The main-side CPU 63 recognizes that the second calculation period has ended based on the value of the second write pointer 604 making one round and becoming “0”. Therefore, a main counter for grasping the end timing of the first calculation period is compared with a configuration in which a dedicated counter for grasping the end timing of the second calculation period is provided separately from the second write pointer 604. The storage capacity of the side RAM 65 is reduced.

The payout rate data in the unit calculation period stored in the second management buffer 602 each time the unit calculation period ends is the payout rate data in the unit calculation period stored in the first management buffer 601 each time the unit calculation period ends. It is the same data as the rate data. As described above, the 0th to 3rd storage areas 601a to 601d of the first management buffer 601 are in a state in which the four payout rate data in each of the unit calculation periods for the latest four times are stored, and The 0th to 9th storage areas 602a to 602j of the management buffer 602 are in a state in which 10 ball output rate data in each of the latest 10 unit calculation periods are stored. The data stored in the storage areas 601a to 601d of the first management buffer 601 are stored in the 0th to 9th storage areas 602a to 602j of the second management buffer 602 in the four unit output periods in the last four unit calculation periods. This matches the data stored in the four storage areas in which the ball rate data is stored.

As illustrated in FIG. 322, in the work area 223 for non-specific control, a first display target area 606 and a second display target area 607 that are display targets on the first to fifth notification display devices 591 to 595. And are provided. The first display target area 606 includes the payout rate data in the entire unit calculation period for four times (specifically, the payout rate data in the entire unit calculation period for the last four times and the payout rate data in the first calculation period). The second display target area 607 is an area in which the payout rate data in the unit calculation period for 10 times (specifically, the payout rate data in the entire unit calculation period for the last 10 times and the second This is an area in which the payout rate data in the calculation period) is stored.

The first display target area 606 includes a first unit update area 606a, a latest area 606b of the first calculation period, a first history area 606c of the first calculation period, and a second history area 606d of the first calculation period. Is provided. Each of these areas 606a to 606d has the same storage capacity, and specifically, each of the payout rate data (numerical information of any one of "0" to "999") can be stored. It has a capacity of 10 bits.

The first unit update area 606a is a counter that stores the payout rate data in the unit calculation period for the last four times. The first unit update area 606a is updated every time the unit calculation period ends. Specifically, after one unit calculation period ends, the final payout rate data in the unit calculation period is written in the first management buffer 601, and then the most recent 4 stored in the first management buffer 601. The payout rate in the latest four unit calculation periods is calculated based on the four payout rate data in each unit calculation period, and the calculated payout rate information is stored in the first unit update area 606a. To be done.

When the first calculation period ends due to the end of the unit calculation period, the 0th to 3rd storage areas 601a to 601d of the first management buffer 601 include the latest four times included in the first calculation period ended this time. It is in a state where four ball output rate data in the unit calculation period are stored. Therefore, when the first calculation period ends, the payout rate data in the first calculation period ended this time is stored in the first unit update area 606a.

The latest area 606b of the first calculation period is a counter in which the payout rate data in the latest first calculation period is stored. The area 606b closest to the first calculation period is updated each time the first calculation period ends. Specifically, the payout rate data in the first calculation period ended this time after the end of one first calculation period is stored in the first unit update area 606a and then stored in the first unit update area 606a. The payout rate data in the first calculation period is also stored in the nearest area 606b in the first calculation period. The payout rate data in the first calculation period stored in the first unit update area 606a is updated when the next unit calculation period ends, but the first calculation stored in the area 606b closest to the first calculation period is performed. The payout rate data in the period is held until the end of the next first calculation period. Therefore, the latest area 606b of the first calculation period is in a state where the payout rate data in the latest first calculation period is continuously stored.

The first history area 606c of the first calculation period is a counter in which the payout rate data in the first calculation period one time before is stored. The first history area 606c of the first calculation period is updated every time the first calculation period ends. Specifically, when one first calculation period ends, the first area is calculated at a timing before storing the payout rate data during the first calculation period ended this time in the area 606b closest to the first calculation period. The payout rate data stored in the area 606b closest to the calculation period is stored in the first history area 606c in the first calculation period. As a result, the state in which the payout rate data for the first calculation period one time before is stored in the first history area 606c for the first calculation period is set.

The second history area 606d of the first calculation period is a counter in which the payout rate data in the first calculation period two times before is stored. The second history area 606d of the first calculation period is updated every time the first calculation period ends. Specifically, when one of the first calculation periods ends, the payout rate data stored in the latest area 606b of the first calculation period is stored in the first history area 606c of the first calculation period rather than stored. At the previous timing, the payout rate data stored in the first history area 606c of the first calculation period is stored in the second history area 606d of the first calculation period. As a result, the state in which the payout rate data for the first calculation period two times before is stored in the second history area 606d for the first calculation period is set.

Since the first display target area 606 is provided with the first history area 606c of the first calculation period and the second history area 606d of the first calculation period, the first to fifth notification display devices 591 to 595 are provided. It is possible to display the payout rate in the first calculation period one time before and display the payout rate in the first calculation period two times before. By displaying whether or not the payout rate in the past first calculation period is within the first normal range (41% to 149%), it is possible to display the first to fifth notification display devices 591 to 595. It is possible to reduce the frequency of confirming, and reduce the burden of monitoring the payout rate of the game hall manager. Further, when an abnormality in the payout rate in the latest first calculation period is confirmed, it is possible to trace back from a time when the abnormality in the payout rate has occurred.

Since the payout rate data in the entire unit calculation period for the last four times is updated each time the unit calculation period ends, it is possible to store a plurality of the payout rate data and grasp the past payout rate data. With the configuration, the number of unit calculation periods corresponding to the plurality of payout rate data is reduced. Specifically, if three pieces of payout rate data in the entire unit calculation period for the latest four times are stored, the range corresponding to the three pieces of payout rate data is the unit calculation period for the latest six times. On the other hand, in the present embodiment, three ball output rate data in the first calculation period, which is updated each time the first calculation period ends, is stored. In this case, the range corresponding to the three payout rate data is the latest 12 unit calculation periods. Thereby, it is possible to grasp the abnormality of the payout rate in the entire unit calculation period for four times over a wide range in the past.

The update frequency of the payout rate data in the entire unit calculation period for the latest four times is higher than the update frequency of the payout rate data in the first calculation period. Therefore, in addition to the latest area 606b in the first calculation period in which the payout rate data in the first calculation period is stored, the first unit update area in which the payout rate data in the entire unit calculation period for the latest four times is stored. The provision of 606a makes it possible to detect the abnormality at an early stage when an abnormality occurs in the ball output rate in the entire unit calculation period for four times.

The second display target area 607 includes a second unit update area 607a, a latest area 607b of the second calculation period, a first history area 607c of the second calculation period, and a second history area 607d of the second calculation period. Is provided. Each of these areas 607a to 607d has the same storage capacity, and specifically, it is possible to store the information on the payout rate (numerical information of any one of "0" to "999"). It has a capacity of 10 bits.

The second unit update area 607a is a counter that stores the payout rate data for the entire last 10 unit calculation periods. The second unit update area 607a is updated every time the unit calculation period ends. Specifically, after the completion of one unit calculation period, the final payout rate data in the unit calculation period is written in the second management buffer 602, and then the most recent 10 stored in the second management buffer 602. The payout rate in the entire last 10 unit calculation periods is calculated based on the 10 payout rate data in each unit calculation period, and the calculated payout rate information is stored in the second unit update area 607a. Is stored.

When the second calculation period ends due to the end of the unit calculation period, the 0th to 9th storage areas 602a to 602j of the second management buffer 602 include the 10 most recent times included in the second calculation period ended this time. It is in a state where 10 ball output rate data in the unit calculation period are stored. Therefore, when the second calculation period ends, the payout rate data in the second calculation period ended this time is stored in the second unit update area 607a.

The latest area 607b of the second calculation period is a counter in which the payout rate data in the latest second calculation period is stored. The latest area 607b of the second calculation period is updated every time the second calculation period ends. Specifically, after one second calculation period ends and the ball output rate data in the second calculation period ended this time is stored in the second unit update area 607a, it is stored in the second unit update area 607a. The payout rate data in the second calculation period is also stored in the latest area 607b in the second calculation period. The payout rate data in the second calculation period stored in the second unit update area 607a is updated when the next unit calculation period ends, but the second calculation stored in the area 607b closest to the second calculation period is performed. The payout rate data in the period is held until the end of the next second calculation period. Therefore, the ball output rate data in the latest second calculation period is continuously stored in the latest area 607b in the second calculation period.

The first history area 607c of the second calculation period is a counter in which the payout rate data in the second calculation period one time before is stored. The first history area 607c of the second calculation period is updated every time the second calculation period ends. Specifically, when one second calculation period ends, the second area is calculated at a timing before storing the payout rate data in the second calculation period ended this time in the area 607b closest to the second calculation period. The payout rate data stored in the area 607b closest to the calculation period is stored in the first history area 607c of the second calculation period. As a result, the first payout area 607c of the second calculation period is in a state where the payout rate data in the second calculation period one time before is stored.

The second history area 607d of the second calculation period is a counter in which the payout rate data in the second calculation period two times before is stored. The second history area 607d of the second calculation period is updated every time the second calculation period ends. Specifically, when one second calculation period ends, the payout rate data stored in the latest area 607b in the second calculation period is stored in the first history area 607c in the second calculation period more than in the first history area 607c. At the previous timing, the payout rate data stored in the first history area 607c of the second calculation period is stored in the second history area 607d of the second calculation period. As a result, the second payout area data 607d of the second calculation period stores the payout rate data in the second calculation period two times before.

Since the second display target area 607 is provided with the first history area 607c of the second calculation period and the second history area 607d of the second calculation period, the first to fifth notification display devices 591 to 595 are provided. It is possible to display the payout rate in the second calculation period one time before and display the payout rate in the second calculation period two times before. By displaying whether or not the payout rate in the past second calculation period is within the second normal range (51% to 133%), it is possible to display the first to fifth notification display devices 591 to 595. It is possible to reduce the frequency of checking and reduce the monitoring burden on the manager of the game hall. Further, when an abnormality in the payout rate in the latest second calculation period is confirmed, it is possible to trace back from a time when the abnormality in the payout rate has occurred.

Since the payout rate data in the entire unit calculation period for the last 10 times is updated each time the unit calculation period ends, a plurality of the relevant payout rate data can be stored to grasp the past relevant payout rate data. With the configuration, the number of unit calculation periods corresponding to the plurality of payout rate data is reduced. Specifically, if three pieces of payout rate data in the entire unit calculation period for the last ten times are stored, the range corresponding to the three pieces of payout rate data is the unit calculation period for the latest twelve times. On the other hand, in the present embodiment, three ball output rate data in the second calculation period, which is updated each time the second calculation period ends, is stored. In this case, the range corresponding to the three payout rate data is the latest 30 unit calculation periods. Thereby, it is possible to grasp the abnormality of the payout rate in the entire unit calculation period for 10 times over a wide range in the past.

The update frequency of the payout rate data in the entire unit calculation period for the last 10 times is higher than the update frequency of the payout rate data in the second calculation period. Therefore, in addition to the latest area 607b in the second calculation period in which the payout rate data in the second calculation period is stored, a second unit update area in which the payout rate data in the entire unit calculation period for the last 10 times is stored. The provision of 607a makes it possible to detect the abnormality at an early stage when an abnormality has occurred in the payout rate in the entire unit calculation period for 10 times.

Based on the payout rate data stored in the first display target area 606 and the second display target area 607, the payout rate in the entire unit calculation period for four times on the first to fifth notification display devices 591 to 595. (The payout rate in the entire unit calculation period for the last 4 times and the payout rate in the first calculation period) and the payout rate in the entire unit calculation period for the latest 10 times (the payout rate in the entire unit calculation period for the latest 10 times and The payout rate in the second calculation period) is displayed. The lower limit (41%) of the first normal range (41% to 149%) is set smaller than the lower limit (51%) of the second normal range (51% to 133%), and the upper limit of the first normal range is set. (149%) is set to be larger than the upper limit (133%) of the second normal range. Therefore, even when the payout rate in the entire unit calculation period for 10 times is out of the second normal range, the payout rate in the entire unit calculation period for 4 times remains within the first normal range. There are cases. In addition, when an abnormality in which the payout rate is out of the normal numerical range occurs temporarily, the payout rate in the entire unit calculation period for four times is out of the first normal range, while the entire unit calculation period for ten times is complete. It is conceivable that the payout rate in 1 may fall within the second normal range. On the other hand, in the present embodiment, the first to fifth notification display devices 591 to 595 display both the payout rate in the entire unit calculation period for four times and the payout rate in the entire unit calculation period for ten times. With such a configuration, it is possible to prevent the abnormality of the payout rate in the entire unit calculation period for four times and the abnormality of the payout rate in the entire unit calculation period for ten times from being overlooked.

Next, with reference to the time chart of FIG. 323, regarding how the first unit update area 606a, the latest area 606b of the first calculation period, the second unit update area 607a, and the latest area 607b of the second calculation period are updated explain. FIG. 323(a) shows the update timing of the latest area 606b of the first calculation period, FIG. 323(b) shows the update timing of the first unit update area 606a, and FIG. 323(c) shows the latest calculation period of the second calculation period. 323(d) shows the update timing of the area 607b, FIG. 323(d) shows the update timing of the second unit update area 607a, FIG. 323(e) shows the end timing of the first calculation period, and FIG. 323(f) shows the second. 323(g) shows the end timing of the unit calculation period.

When the unit calculation period ends at the timings of t1, t2, t3, and t4, as shown in FIG. 323(g), as shown in FIG. 323(b), at the timing of t1, t2, t3, and t4, The unit update area 606a is updated. The first unit update area 606a is based on the four payout rate data stored in the 0th to third storage areas 601a to 601d of the first management buffer 601 at each timing of t1, t2, t3, and t4. The payout rate data in the entire unit calculation period for the latest four times calculated by the above is stored. Further, as shown in FIG. 323(d), the second unit update area 607a is also updated at the timings of t1, t2, t3, and t4. The second unit update area 607a is based on the ten payout rate data stored in the 0th to ninth storage areas 602a to 602j of the second management buffer 602 at each timing of t1, t2, t3, and t4. The payout rate data in the entire unit calculation period for the latest 10 times calculated is stored.

When the first calculation period ends as shown in FIG. 323(e) at the timing of t4, the latest area 606b of the first calculation period is updated as shown in FIG. 323(a). At the timing of t4, the first unit update area 606a stores the payout rate data in the first calculation period ended this time, and the area 606b closest to the first calculation period has the first unit at the timing of t4. The payout rate data stored in the update area 606a is stored. As a result, the ball output rate data for the first calculation period ended this time is also stored in the area 606b closest to the first calculation period. In addition, as already described, at the timing of t4 when the first calculation period ends, the payout in the first calculation period that is one time before the first calculation period ended this time in the first history area 606c of the first calculation period. The rate data is stored, and the payout rate data in the first calculation period two times before the first calculation period ended this time is stored in the second history area 606d of the first calculation period.

Then, as shown in FIG. 323(e), when the unit calculation period ends at the timing of t5, the first unit update area 606a is updated as shown in FIG. 323(b), and at the same time as shown in FIG. 323(d). As shown, the second unit update area 607a is updated. In the first unit update area 606a, at the timing of t5, the latest four times calculated based on the four payout rate data stored in the 0th to third storage areas 601a to 601d of the first management buffer 601. The payout rate data for the entire unit calculation period is stored in the second unit update area 607a in the 0th to ninth storage areas 602a to 602j of the second management buffer 602 at the timing t5. The payout rate data in the entire unit calculation period for the last 10 times calculated based on the 10 payout rate data is stored.

When the second calculation period ends as shown in FIG. 323(f) at the timing of t5, the latest area 607b of the second calculation period is updated as shown in FIG. 323(c). At the timing of t5, the payout rate data in the second calculation period ended this time is stored in the second unit update area 607a, and in the latest area 607b of the second calculation period, the second unit at the timing of t5. The payout rate data stored in the update area 607a is stored. Thereby, the area 607b closest to the second calculation period is in a state where the payout rate data of the second calculation period ended this time is stored. In addition, as already described, at the timing of t5 when the second calculation period ends, the payout in the second calculation period immediately before the second calculation period ended this time in the first history area 607c of the second calculation period. The rate data is stored, and the payout rate data in the second calculation period two times before the second calculation period ended this time is stored in the second history area 607d of the second calculation period.

As described above, the first unit update area 606a is updated every time the unit calculation period ends. If only the final payout rate in the first calculation period can be grasped, the latter half of the front (first) first calculation period and the rear (second) first calculation Even if there is an abnormality in the payout rate in the entire unit calculation period for four times over the first half of the period, the final payout rate in the first calculation period on the front side and the final in the first calculation period on the rear side It is conceivable that the target payout rate falls within the first normal range (41% to 149%). In this case, even if an abnormality occurs in the payout rate in the entire unit calculation period for four times, the abnormality may be overlooked. On the other hand, in the present embodiment, in addition to the final payout rate in the first calculation period, the payout rate in the entire unit calculation period for the latest four times, which is updated each time the unit calculation period ends, is grasped. This is a possible configuration. Thereby, it is possible to prevent the abnormality of the payout rate in the entire unit calculation period for four times from being overlooked.

The second unit update area 607a is updated every time the unit calculation period ends. If only the final payout rate in the second calculation period can be grasped, the second half of the front (first) second calculation period and the rear (second) second calculation Even if an abnormality occurs in the payout rate in the entire unit calculation period for 10 times over the first half of the period, the final payout rate in the front side second calculation period and the final in the rear side second calculation period It is conceivable that the target payout rate falls within the second normal range (51% to 133%). In this case, there is a possibility that the abnormality will be overlooked even if an abnormality occurs in the payout rate in the entire unit calculation period for 10 times. On the other hand, in the present embodiment, in addition to the final payout rate in the second calculation period, the payout rate in the entire unit calculation period for the last 10 times updated each time the unit calculation period ends is grasped. This is a possible configuration. As a result, it is possible to prevent the abnormality of the payout rate in the entire unit calculation period for 10 times from being overlooked.

Next, specific display contents on the first to fifth notification display devices 591 to 595 will be described. As described above, in the first to fifth notification display devices 591 to 595, the payouts stored in the various areas 606a to 606d of the first display target area 606 and the various areas 607a to 607d of the second display target area 607. The rate is displayed. Further, in the first to fifth notification display devices 591 to 595, the setting value is confirmed in the situation where the setting confirmation process (FIG. 136) is being performed, as in the 35th embodiment. A display indicating that the setting value is present and a display indicating the current setting value are displayed, and a display indicating that the setting value is being updated and the current setting value are being displayed in the situation where the setting value updating process (FIG. 137) is being performed. A display showing the set value is displayed. Furthermore, on the first to fifth notification display devices 591 to 595, the check display is performed during the initial check period described later. The display in the situation where the setting confirmation processing (FIG. 136) is being performed, the display in the situation where the setting value updating processing (FIG. 137) is being performed, and the check display will be described later.

The payout rates stored in the various areas 606a to 606d of the first display target area 606 and the various areas 607a to 607d of the second display target area 607 are sequentially notified by the first to fifth notification display devices 591 to 595. To be done. Specifically, every time the display continuation period (specifically, 5 seconds) elapses, the first unit update area 606a→the closest area 606b of the first calculation period→the first history area 606c of the first calculation period→the The second history area 606d for one calculation period→the second unit update area 607a→the nearest area 607b for the second calculation period→the first history area 607c for the second calculation period→the second history area 607d for the second calculation period are predetermined. The payout rate to be notified is switched in the specified order, and the switching of the payout rate to be notified is repeated in the predetermined order.

324(a) to 324(d) show various areas 606a to 606d of the first display target area 606 and various areas 607a of the second display target area 607 in a situation where the calculation start flag 597 is set to "1". It is explanatory drawing for demonstrating the display content of the 1st-5th notification display apparatuses 591-595 when the payout rate stored in -607d is notified. FIG. 324(a) shows an example of the display contents of the first to fifth notification display devices 591-595 when the payout rate stored in the first unit update area 606a is notified, and FIG. Shows an example of the display contents of the first to fifth notification display devices 591 to 595 when the payout rate stored in the nearest area 606b of the first calculation period is notified, and FIG. 324(c) shows the second FIG. 324(d) shows a second calculation example of the display contents of the first to fifth notification display devices 591 to 595 when the payout rate stored in the first history area 607c of the calculation period is notified. An example of the display contents of the first to fifth notification display devices 591 to 595 when the payout rate stored in the second history area 607d of the period is notified is shown.

As shown in FIGS. 324(a) to 324(d), the first notification display device 591 has eight display segments 611. Of the eight display segments 611 in the first notification display device 591, seven display segments 611 are rod-shaped light emitting regions having the same shape and the same size. Are arranged in. On the other hand, one display segment 611 is a circular light emitting region and is provided at the lower right position with respect to the seven display segments 611 arranged in the shape of “8”. ..

As shown in FIGS. 324(a) to 324(d), each of the second to fifth notification display devices 592 to 595 has seven display segments 612 to 615. Each of the seven display segments 612 to 615 is a rod-shaped light emitting region having the same shape and the same size, and is arranged so as to generate the shape of "8".

Even when the payout rate of any of the various areas 606a to 606d in the first display target area 606 and the various areas 607a to 607d in the second display target area 607 is notified, the first to fifth notification display devices 591. At least one of the display segments 611 to 615 is in a light emitting state.

In the first notification display device 591, a display indicating that the payout rate stored in the first display target area 606 is notified in the first to fifth notification display devices 591 to 595, and A display indicating that the situation is informing of the payout rate stored in the second display target area 607 is performed. Specifically, when notifying the payout rate of any of the various areas 606a to 606d in the first display target area 606, as shown in FIGS. 323(a) and 323(b), the first notification display The character "d" is displayed on the device 591. Further, when notifying the payout rate of any of the various areas 607a to 607d in the second display target area 607, as shown in FIGS. 323(c) and 323(d), the first notification display device 591 is displayed. "D." is displayed. When the information other than the payout rate is notified on the first to fifth notification display devices 591 to 595, the characters “d” and “d.” are displayed on the first notification display device 591. There is no. By confirming that the character "d" is displayed on the first notification display device 591, the manager of the gaming hall displays the first display on the first to fifth notification display devices 591-595. By confirming that the payout rate stored in the target area 606 is notified, and by confirming that the character “d.” is displayed on the first notification display device 591. It is possible to know that the payout rate stored in the second display target area 607 is notified by the first to fifth notification display devices 591 to 595.

In the second notification display device 592, which of the various areas 606a to 606d of the first display target area 606 and the various areas 607a to 607d of the second display target area 607 is being notified of the throwing rate? Is displayed. Specifically, in the situation where the payout rate of the first unit update area 606a is informed, the character "A" is displayed on the second informing display device 592 as shown in FIG. 324(a). .. Further, even in a situation where the payout rate of the second unit update area 607a is informed, the letter "A" is similarly displayed on the second informing display device 592. When information other than the payout rate of the first unit update area 606a or the second unit update area 607a is notified on the second notification display device 592, the character "A" is displayed on the second notification display device 592. It is never displayed. The manager of the game hall confirms that the letter "A" is displayed on the second notification display device 592, and the first unit is displayed on the first to fifth notification display devices 591-595. It can be understood that the payout rate of the update area 606a or the second unit update area 607a is notified. Since the display indicating that the payout rate of the unit update areas 606a and 607a is displayed is common in the first display target area 606 and the second display target area 607, the display of the second notification display device 592. And the corresponding relationship with the type of the payout rate displayed on the first to fifth notification display devices 591 to 595 is easy to understand.

In a situation where the payout rate of the area 606b closest to the first calculation period is informed, the letter "L" is displayed on the second annunciator display device 592 as shown in FIG. 324(a). Further, even in the situation where the payout rate of the area 607b closest to the second calculation period is informed, the letter "L" is similarly displayed on the second informing display device 592. When information other than the payout rate of the latest area 606b of the first calculation period or the latest area 607b of the second calculation period is notified on the second notification display device 592, "L" is displayed on the second notification display device 592. The character "" is never displayed. The manager of the game hall confirms that the letter "L" is displayed on the second notification display device 592, and thus the first calculation is performed on the first to fifth notification display devices 591-595. It can be understood that the payout rate of the latest area 606b of the period or the latest area 607b of the second calculation period is notified. Since the display indicating that the payout rates of the latest areas 606b and 607b are displayed in common in the first display target area 606 and the second display target area 607, the display of the second notification display device 592 is , The first to fifth notification display devices 591 to 595 and the types of the payout rates displayed on the display devices 591 to 595 are easy to understand.

In a situation where the payout rate of the first history area 607c in the second calculation period is informed, the letter “F” is displayed on the second informing display device 592 as shown in FIG. 324(a). Further, even in a situation where the payout rate of the first history area 606c in the first calculation period is informed, the letter “F” is similarly displayed on the second informing display device 592. When information other than the payout rate of the first history area 606c of the first calculation period or the first history area 607c of the second calculation period is notified on the second notification display device 592, the second notification display device 592 is displayed. The letter "F" is not displayed at. The manager of the game hall confirms that the letter "F" is displayed on the second notification display device 592, and thus the first calculation is performed on the first to fifth notification display devices 591-595. It can be understood that the payout rate of the first history area 606c of the period or the first history area 607c of the second calculation period is notified. Since the display indicating that the payout rates of the first history areas 606c and 607c are displayed is common in the first display target area 606 and the second display target area 607, the second notification display device 592 is displayed. The correspondence between the display and the types of payout rates displayed on the first to fifth notification display devices 591 to 595 is easy to understand.

In a situation where the payout rate of the second history area 607d in the second calculation period is informed, the letter "E" is displayed on the second annunciator display device 592 as shown in FIG. 324(a). Further, also in a situation where the payout rate of the second history area 606d in the first calculation period is informed, the letter "E" is similarly displayed on the second informing display device 592. When information other than the payout rate of the second history area 606d of the first calculation period or the second history area 607d of the second calculation period is notified on the second notification display device 592, the second notification display device 592 is displayed. The letter "E" is never displayed. The manager of the game hall confirms that the letter "E" is displayed on the second notification display device 592, and thus the first calculation is performed on the first to fifth notification display devices 591-595. It can be understood that the payout rate of the second history area 606d of the period or the second history area 607d of the second calculation period is notified. Since the display indicating that the payout rate of the second history areas 606d and 607d is displayed is common in the first display target area 606 and the second display target area 607, the second notification display device 592 is displayed. The correspondence between the display and the types of ball output rates displayed on the first to fifth notification display devices 591 to 595 is easy to understand.

The manager of the gaming hall, based on the combination of the display of the first notification display device 591 and the display of the second notification display device 592, various areas 606a to 606d of the first display target area 606 and the second display target area. Of the various areas 607a to 607d of 607, the area to be notified can be grasped. For example, when the display of the first to second notification display devices 591 to 592 is “dA”, it can be understood that the first unit update area 606a is the notification target, and the first to second 2 When the display of the notification display devices 591 to 592 is “d.L”, it can be understood that the latest area 607b of the second calculation period is the notification target.

On the third to fifth notification display devices 593 to 595, any number from "0" to "9" is displayed as a display corresponding to the payout rate. In this case, when a number is displayed on the second notification display device 592, four numbers are arranged on the second to fifth notification display devices 592 to 595, making it difficult to grasp the payout rate. Will end up. On the other hand, by displaying the alphabet “A”, “L”, “F”, or “E” on the second notification display device 592, the display on the second notification display device 592 It is possible to distinguish and grasp the display of the numbers corresponding to the payout rates displayed on the third to fifth notification display devices 593 to 595.

On the third to fifth display devices 593 to 595, three numbers corresponding to the payout rate that is the notification target are displayed. As described above, the payout rate information is stored as 3-digit numerical information in the range of “0” to “999”. The hundredth digit of the payout rate is displayed on the third notification display device 593, and the tenth digit of the payout rate is displayed on the fourth notification display device 594. The first digit of the ball rate is displayed on the fifth notification display device 595.

If the information of the payout rate is not yet stored in the areas 606a to 606d and 607a to 607d that are the notification targets in the first display target area 606 and the second display target area 607, the third to fifth notifications are performed. The character "0" is displayed on each of the display devices 593 to 595. In addition, in the first display target area 606 and the second display target area 607, when the information of the payout rate is not yet stored in the areas 606a to 606d and 607a to 607d which are the notification targets, the third to fifth areas are stored. The notification display devices 593 to 595 may be configured to display a hyphen (“-”) symbol. The hyphen (“-”) symbol indicates that one display segment 611 to 615 at the center of each of the notification display devices 591 to 595 is in a light emitting state and the other display segments 611 to 615 are in a light off state. It is displayed by doing.

As described above, the payout rate information is stored as numerical information of “0” to “999”. When the calculated payout rate is higher than 999%, the numerical value information of "999" is stored as the information of the payout rate. When displaying the information on the payout rate as 4-digit numerical information, another notification display device is required in addition to the first to fifth notification display devices 591 to 595. As described above, the first normal range is the numerical range of 41% to 149%, and the second normal range is the numerical range of 51% to 133%. Therefore, even if the payout rate exceeding 999% is displayed as 999%, an abnormality occurs in which the payout rate exceeds the normal range (first normal range or second normal range), and the degree of the abnormality is It is possible to grasp that it is serious. In the present embodiment, the upper limit of the payout rate displayed on the first to fifth notification display devices 591 to 595 is set to 999%, thereby suppressing an increase in the number of the notification display devices 591 to 595. However, when the payout rate exceeds the upper limit of the normal range (first normal range or second normal range), not only whether there is an abnormality in which the payout rate exceeds the upper limit of the normal range, but also to the extent of the abnormality. It is possible to grasp.

In the present embodiment, in a situation where the setting value is being confirmed, a display indicating that the setting value is being confirmed on the first to fifth notification display devices 591 to 595 and the current setting value Is displayed. Specifically, the display indicating the hyphen ("-") symbol is performed on the first to third notification display devices 591 to 593, and the display indicating the character "k" is displayed on the fourth notification display device 594. Then, the fifth notification display device 595 displays a number corresponding to the current set value. For example, when the current set value is "2", the display on the first to fifth notification display devices 591 to 595 is "-k2". A situation in which the manager of the game hall confirms the set value on the first to fifth notification display devices 591 to 595 based on the display of the fourth notification display device 594 being "k". It is possible to know that the display corresponding to is displayed, and also to know the current set value by checking the number displayed on the fifth notification display device 595.

In the present embodiment, in the situation where the setting value is being updated, a display indicating that the setting value is being updated on the first to fifth notification display devices 591 to 595 and the current setting value Is displayed. Specifically, the display indicating the hyphen ("-") symbol is performed on the first to third notification display devices 591 to 593, and the display indicating the character "H" is displayed on the fourth notification display device 594. Then, the fifth notification display device 595 displays a number corresponding to the current set value. For example, when the current set value is "4", the display on the first to fifth notification display devices 591 to 595 is "-H4". The manager of the game hall is updating the set value on the first to fifth notification display devices 591 to 595 based on the display of the fourth notification display device 594 being "H". It is possible to know that the display corresponding to is displayed and the current set value can be known by checking the number displayed on the fifth notification display device 595.

As described above with reference to FIG. 119 in the thirty-third embodiment, the main control board 61 is provided with the first to fifth display circuits 261 to 265. In the present embodiment, the fifth display circuit 265 is provided corresponding to the first to fifth notification display devices 591 to 595. Further, as already described in the thirty-third embodiment, the first display circuit 261 is provided so as to correspond to the special figure display portion 37a, and the second display circuit 262 corresponds to the special figure reservation display portion 37b. The third display circuit 263 is provided to correspond to the universal figure display portion 38a, and the fourth display circuit 264 is provided to correspond to the universal figure reservation display portion 38b.

As already described in the 33rd embodiment, one display IC 266 is provided on the main control board 61 so as to be common to all the first to fifth display circuits 261 to 265. The main CPU 63 and the display IC 266 are electrically connected using the type data signal line LN1, the type clock signal line LN2, the display data signal line LN3, and the display clock signal line LN4. The CPU 63 supplies the display IC 266 with display data and type data indicating which of the first to fifth display circuits 261 to 265 the display data corresponds to.

As described above with reference to FIG. 120A in the 33rd embodiment, the first to fifth display data buffers 271 to 275 are provided in the work area 221 for specific control. In the present embodiment, display data for causing the first to fifth notification display devices 591 to 595 to perform a predetermined display is stored in the fifth display data buffer 275.

As described above with reference to FIG. 120(b) in the thirty-third embodiment, the display area setting area 276 is provided in the work area 223 for non-specific control. In the present embodiment, the display target setting area 276 is set with display data including display type data and payout rate display data. The display type data is a first notification display that indicates that the notification target of the first to fifth notification display devices 591 to 595 is the payout rate (display of characters "d" or "d."). The display data to be performed by the device 591 and the payout rate of the notification target correspond to any of the various areas 606a to 606d of the first display target area 606 and the various areas 607a to 607d of the second display target area 607. Display data for causing the second annunciator display device 592 to perform a display (display of any one of the characters "A", "L", "F", and "E") indicating whether or not it is present. In addition, the payout rate display data includes display data for causing the third notification display device 593 to perform a display corresponding to the hundreds digit in the payout rate of the notification target, and a display data for the payout rate of the notification target. The display data for causing the fourth notification display device 594 to perform the display corresponding to the digit of the place and the display corresponding to the digit of the first place in the payout rate of the notification target are displayed on the display device 595 for the fifth notification. And display data to be executed.

In this embodiment, the display data set in the display target setting area 276 in step SL409 of the normal setting process (FIG. 328) described later is set in the fifth display data buffer 275, and the second timer interrupt process ( The display data set in the fifth display data buffer 275 in FIG. 134) is transmitted to the display IC 266. Similar to the 33rd embodiment, the display IC 266 designates the fifth display circuit 265 in the situation where the display data received from the main CPU 63 is supplied to all the first to fifth display circuits 261 to 265. A fifth selection signal for causing the fifth display circuit 265 to receive and use the display data based on the type data is transmitted. Thereby, the display data supplied to all of the first to fifth display circuits 261 to 265 is received and used only in the fifth display circuit 265.

The fifth display circuit 265 provides data corresponding to the supplied display data to each of the plurality of display segments 611 to 615 provided in each of the first to fifth notification display devices 591 to 595. As a result, the display segments 611 to 615 of the first to fifth notification display devices 591 to 595 are turned on or off in a manner corresponding to the display data provided to the fifth display circuit 265. In this case, the fifth display circuit 265 can store and hold the provided display data for a predetermined period (for example, 16 milliseconds), but after the predetermined period elapses, the display data gradually becomes all "0". It will approach the state of. Therefore, the display segments 611 to 615 of the first to fifth notification display devices 591 to 595 which are in the light emitting state by the display data provided to the fifth display circuit 265 have new display data as the fifth display circuit 265. The light is gradually turned off when a predetermined period of time elapses without being provided. Moreover, not only when the display contents of the 1st-5th notification display devices 591-595 are changed by such a structure, the display contents of the 1st-5th notification display devices 591-595 are changed. Even if the display data is not output, the same display data as the previous output processing of the display data is supplied to the fifth display circuit 265.

As described above, the first notification display device 591 is provided with eight display segments 611, and each of the second to fifth notification display devices 592 to 595 has the display segments 612 to 615. Seven are provided. On the other hand, the display data is provided in 8-bit units. When the display data of the first to fifth notification display devices 591 to 595 is provided to the fifth display circuit 265, 8-bit display data corresponding to the first notification display device 591 is provided as 8-bit unit data. Then, the 7-bit display data corresponding to the second notification display device 592 is provided as 8-bit unit data, and thereafter the 7-bit display data corresponding to the third notification display device 593 is provided in 8-bit units. Data, and then 7-bit display data corresponding to the fourth notification display device 594 is provided as 8-bit data, and finally, 7-bit display data corresponding to the fifth notification display device 595. Is provided as 8-bit unit data.

Next, a processing configuration for making it possible to notify the various payout rates as described above will be described.

As described above in the 35th embodiment, the main CPU 63 executes the management process in step S8920 of the first timer interrupt process (FIG. 133). In the management process, similarly to the management process (FIG. 70) in the fifteenth embodiment, the program of the management execution process corresponding to the non-specific control is read in step S3803. Then, in this management execution process (FIG. 71), the check process is executed in step S3908, as in the fifteenth embodiment.

FIG. 325 is a flowchart showing the check processing. The processes of steps SL101 to SL114 in the check process are executed by using the non-specific control program and the non-specific control data in the main CPU 63.

In the check process, if the front door frame 14 is in the closed state (step SL101: YES), a ball entry management process is executed (step SL102). The entry management process is executed in all game states without distinguishing the game states. Specifically, the entry management process is executed in a game state that is neither the open/close execution mode nor the high frequency support mode, the game state that is the open/close execution mode, and the game state that is the high frequency support mode. In the winning ball management process, when it is determined that one gaming ball is detected by the first winning hole detection sensor 42a, when one gaming ball is detected by the second winning hole detection sensor 43a, Alternatively, when it is determined that one gaming ball is detected by the third winning opening detection sensor 44a, the value of the general winning counter 596a is incremented by 1. Further, when it is determined that one game ball is detected by the special electric detection sensor 45a, the value of the special electric prize winning counter 596b is incremented by 1, and one game ball is detected by the first working opening detection sensor 46a. When the determination is made, the value of the first operation counter 596c is incremented by 1, and when it is determined that one game ball is detected by the second operation opening detection sensor 47a, the value of the second operation counter 596d is incremented by 1, When it is determined that one gaming ball has been detected by the out mouth detection sensor 48a, the value of the out counter 596e is incremented by 1. As a result, it becomes possible for the main CPU 63 to grasp the entry history into each entry portion 24a, 31 to 34 in the entire game state.

On the other hand, when the front door frame 14 is in the open state (step SL101: YES), the process proceeds to step SL103 without executing the entry management process (step SL102). Since the game area PA is formed by the space defined by the back surface of the window panel 52 provided on the front door frame 14 and the front surface of the game board 24, the front door frame 14 is opened. Even if the game area PA is opened toward the front and the game ball is shot toward the game area PA in that situation, the game ball cannot normally flow down the game area PA. Further, when the game balls enter the ball entrance portions 24a, 31 to 34 in a state where the front door frame 14 is in the open state, the game hall manager may perform maintenance or trouble elimination. This is a case where the front door frame 14 is opened and game balls enter due to care. Since the entry of such a game ball is not the entry of the game ball in the execution state of the regular game, it is not necessary to manage the entry of such a game ball. Therefore, in the check process, the entry management process (step SL102) is not executed when the front door frame 14 is in the open state as described above.

If an affirmative determination is made in step SL101, or if the process of step SL102 has been performed, the current payout rate calculation process is executed (step SL103). In the current payout rate calculation processing, first, the calculation area 598 and the current payout rate area 599 in the work area 223 for non-specific control are cleared to “0”. After that, the total payout number of the game balls is calculated using the values stored in the various counters 596a to 596e of the incoming ball number counter area 596, and the calculated total payout number of the game balls is set in the calculation area 598. .. Further, the total number of game balls discharged from the game area PA is calculated by summing the values of the various counters 596a to 596e, and the calculated total number of game balls is set in the current payout rate area 599. Then, the total payout number of the game balls set in the calculation area 598 is divided by the total number of the game balls discharged from the game area PA set in the current payout rate area 599, and the result is multiplied by 100. Is calculated, and the calculated current payout rate is stored in the calculation area 598. As described above, the current payout rate is calculated as 3-digit numerical information in the range of "0" to "999". When the calculation result is a numerical value exceeding "999", numerical value information of "999" is stored in the calculation area 598 as the current payout rate.

After that, the overwriting process of the current payout rate area 599 is executed (step SL104). In the overwrite processing, the current payout rate data stored in the calculation area 598 is overwritten in the current payout rate area 599. The current payout rate data overwritten in the current payout rate area 599 is the calculation result of the current payout rate calculation processing (step SL103).

Then, it is determined whether or not “1” is set in the calculation start flag 597 in the work area 223 for non-specific control (step SL105). As described above, the calculation start flag 597 has a value of “0” when the supply of operating power to the pachinko machine 10 is started for the first time after the pachinko machine 10 is manufactured. The value of the calculation start flag 597 also becomes “0” when the work area 223 for non-specific control including the calculation start flag 597 is cleared to “0” and initialized.

When it is determined in step SL105 that "1" is not set in the calculation start flag 597, the total discharge number calculation processing is executed (step SL106). In the calculation processing of the total discharged number, by calculating the total value of the values stored in the various counters 596a to 596e of the incoming ball number counter area 596, all the game states (either the open/close execution mode or the high frequency support mode) In the non-playing game state, the game state of the open/close execution mode, and the game state of the high-frequency support mode), the total number of game balls discharged from the game area PA is calculated.

After that, it is determined whether or not the total discharge number calculated in step SL106 (the total number of game balls discharged from the game area PA) is more than the calculation start reference number of 300 (step SL107). .. When an affirmative determination is made in step SL107, the calculation start flag 597 is set to "1" (step SL108), and the processing for clearing the number of entered balls counter area 596 is executed (step SL109). In the clearing process, the values of the various counters 596a to 596e in the incoming ball number counter area 596 are cleared to "0". As a result, the first unit calculation period is started.

On the other hand, when it is determined that the calculation start flag 597 is set to "1" in step SL105, the total discharge number calculation processing is executed (step SL110). In the calculation process, similar to the calculation process of the total discharged number in step SL106, by calculating the total value of the values stored in the various counters 596a to 596e of the incoming ball number counter area 596, in all the gaming states, The total number of game balls discharged from the game area PA is calculated. Then, it is determined whether or not the calculated total discharged number (total number of game balls discharged from the game area PA) is 6000 or more, which is the unit reference number (step SL111).

When an affirmative determination is made in step SL111, a payout rate storage process of writing the current payout rate data stored in the current payout rate area 599 to the first management buffer 601 and the second management buffer 602 is performed. Execute (step SL112). In this way, in the payout rate storage process (step SL112), the total number of game balls discharged from the game area PA becomes 6000 or more, which is the unit reference number, in one full game state, and one unit calculation period ends. If executed.

FIG. 326 is a flowchart showing the payout rate storage processing. The processing from step SL201 to step SL224 in the payout rate storage processing is executed using the non-specific control program and non-specific control data in the main CPU 63.

In the payout rate storage processing, first, the current payout rate data stored in the current payout rate area 599 in the work area 223 for non-specific control is grasped (step SL201). The current payout rate area 599 stores the final payout rate data for the unit calculation period ended this time. After that, based on the value of the first write pointer 603 in the work area 223 for non-specific control, the storage areas 601a to 601d to be the write destination among the 0th to third storage areas 601a to 601d in the first management buffer 601 are selected. It is specified (step SL202). As described above, when the value of the first write pointer 603 is “n” (n is any integer of 0 to 3), the nth storage areas 601a to 601d are specified as the write destination storage areas 601a to 601d. To do.

After that, the overdrawing rate data is overwritten (step SL203). In the overwriting process, the current payout rate data grasped in step SL201 is overwritten in the storage areas 601a to 601d of the first management buffer 601 identified in step SL202. Thereby, the payout rate data in the unit calculation period ended this time is stored in the storage areas 601a to 601d.

After that, the first write pointer 603 is updated (step SL204). In the updating process, the value of the first write pointer 603 is incremented by 1, and when the value after the increment of 1 exceeds the maximum value (specifically, “3”), the value of the first write pointer 603 is set to “0”. clear.

Then, it is determined whether the first notification start flag 608 provided in the work area 223 for non-specific control is set to "1" (step SL205). The first notification start flag 608 indicates whether or not it is a situation in which the first to fifth notification display devices 591 to 595 display the payout rates of the various areas 606a to 606d in the first display target area 606. This is a flag for the main CPU 63 to know. The first notification start flag 608 has a value of “0” when the supply of operating power to the pachinko machine 10 is started for the first time after the pachinko machine 10 is manufactured. The value of the first notification start flag 608 is also “0” when the non-specific control work area 223 including the first notification start flag 608 is cleared and initialized to “0”. “1” is set in the first notification start flag 608 when four ball output rate data in each unit calculation period for four times is stored in the storage areas 601a to 601d of the first management buffer 601. Is set. In the state where the value of the first notification start flag 608 is “0”, the payout rate data is stored in at least one storage area 601a to 601d of the four storage areas 601a to 601d of the first management buffer 601. Corresponds to the absence. When "1" is not set in the first notification start flag 608, the payouts stored in the various areas 606a to 606d of the first display target area 606 in the first to fifth notification display devices 591 to 595. The rate is not displayed. Details of the display contents of the first to fifth notification display devices 591 to 595 when the first notification start flag 608 is not set to "1" will be described later.

When a negative determination is made in step SL205, it is determined whether or not the value of the first write pointer 603 has made one round (step SL206). In step SL206, when the value of the first write pointer 603 after being updated in step SL204 is "0", it is determined that the value of the first write pointer 603 has made one round. When an affirmative determination is made in step SL206, it is in a state in which the storage area 601a to 601d of the first management buffer 601 stores four ball output rate data in each unit calculation period for four times. "1" is set in the first notification start flag 608 (step SL207).

When a positive determination is made in step SL205 or when the process of step SL207 is performed, the first payout rate calculation process is executed (step SL208). In the first payout rate calculation processing, first, the calculation area 598 in the work area 223 for non-specific control is cleared to “0”, and the calculation area 598 is stored in the 0th storage area 601a of the first management buffer 601. The payout rate data (numerical information of any one of "0" to "999") is set. After that, by adding the three payout rates stored in the first to third storage areas 601b to 601d of the first management buffer 601 to the value of the calculation area 598, the four payout rates are calculated. Calculate the total value. After that, the value in the calculation area 598 is divided by “4” to calculate the payout rate in the entire unit calculation period for the latest four times, and the calculated payout rate is stored in the calculation area 598. As described above, the payout rate in the entire unit calculation period for the latest four times is calculated as 3-digit numerical information in the range of “0” to “999”. By executing the first payout rate calculation processing in step SL208, the calculation area 598 is in a state in which the payout rate data for the entire unit calculation period for the last four times is stored.

After that, the overwrite processing of the first unit update area 606a is executed (step SL209). In the overwriting process, the first unit update area 606a is overwritten with the ball output rate data in the entire unit calculation period for the latest four times calculated in step SL208. In this way, the payout rate data stored in the first unit update area 606a is updated to the payout rate data for the latest four unit calculation periods each time one unit calculation period ends.

In the first payout rate calculation processing in step SL208 and the overwrite processing of the first unit update area 606a in step SL209, "1" is set in the first notification start flag 608 (the affirmative determination is made in step SL205). Is executed or the process of step SL207 is performed). On the other hand, when "1" is not set in the first notification start flag 608 (step SL205: NO, step SL206: NO), the processes of step SL208 and step SL209 are not executed. When "1" is not set in the first notification start flag 608, it means that the number of ball output rate data for calculating the ball output rate in the entire unit calculation period for the last four times is insufficient. .. In this case, if the processing of step SL208 and step SL209 is configured to be executed, the payout rate data for the entire unit calculation period for the latest 1 to 3 times is stored in the first unit update area 606a. The first normal range (41% to 149%) is a normal range of the payout rate in the entire unit calculation period for four times, and the normal range of the payout rate in the entire unit calculation period for one to three times is a different numerical range. Is. Therefore, when the ball output rate data for the entire unit calculation period for the most recent 1-3 times is stored in the first unit update area 606a and displayed on the first to fifth notification display devices 591 to 595, It becomes impossible to accurately judge whether there is an abnormality in the ball rate. In the present embodiment, the first payout rate calculation processing in step SL208 and the overwrite processing of the first unit update area 606a in step SL209 are executed on condition that "1" is set in the first notification start flag 608. With the configuration, it is prevented that the first to fifth notification display devices 591 to 595 display the payout rate in the entire unit calculation period for one to three times.

Then, it is determined whether the first calculation period has ended (step SL210). In step SL210, when the value of the first write pointer 603 after being updated in step SL204 is “0”, it is determined that it is the timing when the first calculation period ends. When an affirmative determination is made in step SL210, the process for updating the latest area 606b of the first calculation period, the first history area 606c of the first calculation period, and the second history area 606d of the first calculation period ( The processing of steps SL211 to SL212) is executed.

Specifically, first, the first data shift process is executed (step SL211). In the first data shift process, the information stored in the immediate area 606b of the first calculation period, the first history area 606c of the first calculation period, and the second history area 606d of the first calculation period in the first display target area 606. Are shifted in the order of the first history area 606c of the first calculation period→the second history area 606d of the first calculation period, the nearest area 606b of the first calculation period→the first history area 606c of the first calculation period. Thereby, the payout rate data in the first calculation period two times before the first calculation period ended this time is stored in the second history area 606d of the first calculation period, and one time before the first calculation period ended this time. The payout rate data in the first calculation period is stored in the first history area 606c in the first calculation period. In the first data shift processing, the LDIR instruction is used when the above information shift is performed. In the LDIR instruction, the information stored in the storage area is shifted (copied) to the storage area by designating the address of the storage area of the information and the address of the storage area of the information. Becomes Further, in the first data shift processing in step SL211, after the information shift as described above, the nearest area 606b of the first calculation period is cleared to “0”.

After that, the payout rate data stored in the first unit update area 606a is stored in the area 606b closest to the first calculation period (step SL212). As described above, the first unit update area 606a stores the payout rate for the last four unit calculation periods. When the value of the first write pointer 603 makes one round and one first calculation period ends, the latest four unit calculation periods are four unit calculation periods included in the first calculation period ended this time. For this reason, the final payout rate data in the first calculation period ended this time is stored in the first unit update area 606a, and in step SL209, the latest ball output rate data in the area 606b closest to the first calculation period is also stored. The final payout rate data for one calculation period is stored.

If a negative determination is made in step SL206, a negative determination is made in step SL210, or if the process of step SL212 is performed, the current payout rate stored in the current payout rate area 599. The data is grasped (step SL213). As described above, the current payout rate area 599 stores the payout rate data in the unit calculation period ended this time. After that, based on the value of the second write pointer 604 in the non-specific control work area 223, the storage areas 602a to 602j to be the write destination among the 0th to 9th storage areas 602a to 602j in the second management buffer 602 are selected. It is specified (step SL214). As described above, when the value of the second write pointer 604 is “m” (m is any integer from 0 to 9), the mth storage areas 602a to 602j are specified as the write destination storage areas 602a to 602j. To do.

After that, the overdrawing rate data is overwritten (step SL215). In the overwrite processing, the current payout rate data grasped in step SL213 is overwritten in the storage areas 602a to 602j of the second management buffer 602 specified in step SL214. Thereby, the payout rate data in the unit calculation period ended this time is stored in the storage areas 602a to 602j.

After that, the second write pointer 604 is updated (step SL216). In the update process, the value of the second write pointer 604 is incremented by 1, and when the value after the increment of 1 exceeds the maximum value (specifically, “9”), the value of the second write pointer 604 is set to “0”. clear.

Then, it is determined whether or not the second notification start flag 609 provided in the non-specific control work area 223 is set to "1" (step SL217). The second notification start flag 609 indicates whether or not the situation is such that the first to fifth notification display devices 591 to 595 display the payout rates of the various areas 607a to 607d in the second display target area 607. This is a flag for the main CPU 63 to know. The second notification start flag 609 has a value of “0” when the supply of operating power to the pachinko machine 10 is started for the first time after the pachinko machine 10 is manufactured. The value of the second notification start flag 609 is also “0” when the non-specific control work area 223 including the second notification start flag 609 is cleared and initialized to “0”. “1” is set in the second notification start flag 609 when 10 ball output rate data in each unit calculation period for 10 times is stored in the storage areas 602a to 602j of the second management buffer 602. Is set. In the state where the value of the second notification start flag 609 is “0”, the payout rate data is stored in at least one storage area 602a to 602j of the 10 storage areas 602a to 602j of the second management buffer 602. Corresponds to the absence. When "1" is not set in the second notification start flag 609, the payouts stored in the various areas 607a to 607d of the second display target area 607 in the first to fifth notification display devices 591 to 595. The rate is not displayed. Details of the display contents of the first to fifth notification display devices 591 to 595 when the second notification start flag 609 is not set to "1" will be described later.

When a negative determination is made in step SL217, it is determined whether or not the value of the second write pointer 604 has made one round (step SL218). In step SL218, when the value of the second write pointer 604 after being updated in step SL216 is “0”, it is determined that the value of the second write pointer 604 has made one round. When an affirmative determination is made in step SL218, the storage area 602a to 602j of the second management buffer 602 is in a state in which 10 ball output rate data in each of the latest 10 unit calculation periods are stored. This means that the second notification start flag 609 is set to "1" (step SL219).

When an affirmative determination is made in step SL217, or when the processing of step SL219 is performed, the second payout rate calculation processing is executed (step SL220). In the second payout rate calculation processing, first, the calculation area 598 in the work area 223 for non-specific control is cleared to “0”, and the payout rate data ((0) stored in the 0th storage area 602a of the second management buffer 602 ( Numerical information of "0" to "999") is set in the calculation area 598. After that, by adding the nine payout rates stored in the first to ninth storage areas 602b to 602j of the second management buffer 602 to the value of the calculation area 598, the payout rate of ten payouts is calculated. Calculate the total value. Then, the value in the calculation area 598 is divided by “10” to calculate the payout rate in the entire unit calculation period for the last 10 times, and the calculated payout rate is stored in the calculation area 598. As already described, the payout rate in the entire unit calculation period for the last 10 times is calculated as 3-digit numerical information in the range of “0” to “999”. As a result, the payout rate in the entire unit calculation period for the last 10 times is stored in the calculation area 598.

After that, the overwriting process of the second unit update area 607a is executed (step SL221). In the overwriting process, the second unit update area 607a is overwritten with the ball output rate data for the entire unit calculation period for the last 10 times calculated in step SL220. In this way, the payout rate data stored in the second unit update area 607a is updated to the payout rate data for the entire last ten unit calculation periods each time one unit calculation period ends.

In the second payout rate calculation process in step SL220 and the overwriting process of the second unit update area 607a in step SL221, "1" is set in the second notification start flag 609 (the affirmative determination is made in step SL217). Is executed or the process of step SL219 is performed). On the other hand, if "1" is not set in the second notification start flag 609 (step SL217: NO, step SL218: NO), the processes of step SL220 and step SL221 are not executed. When "1" is not set in the second notification start flag 609, it means that the number of ball output rate data for calculating the ball output rate in the entire unit calculation period for the last 10 times is insufficient. .. In this case, if the processing of step SL220 and step SL221 is configured to be executed, the payout rate data for the entire unit calculation period for the most recent 1 to 9 times is stored in the second unit update area 607a. The second normal range (51% to 133%) is a normal range of the payout rate in the entire unit calculation period for 10 times, and the normal range of the payout rate in the entire unit calculation period for 1 to 9 times is a different numerical range. Is. Therefore, when the ball output rate data for the entire unit calculation period for the most recent 1 to 9 times is stored in the second unit update area 607a and displayed on the first to fifth notification display devices 591 to 595, It becomes impossible to accurately judge whether or not the ball rate is abnormal. In the present embodiment, the second payout rate calculation processing in step SL220 and the overwriting processing of the second unit update area 607a in step SL221 are executed on condition that "1" is set in the second notification start flag 609. With the configuration, it is prevented that the first to fifth notification display devices 591 to 595 display the payout rate in the entire unit calculation period of 1 to 9 times.

Then, it is determined whether or not the second calculation period has ended (step SL222). In step SL222, when the value of the second write pointer 604 updated in step SL216 is “0”, it is determined that it is the timing when the second calculation period ends. When an affirmative determination is made in step SL222, the process for updating the latest area 607b of the second calculation period, the first history area 607c of the second calculation period, and the second history area 607d of the second calculation period ( The processing of steps SL223 to SL224) is executed.

Specifically, first, the second data shift process is executed (step SL223). In the second data shift process, the information stored in the immediate area 607b of the second calculation period, the first history area 607c of the second calculation period, and the second history area 607d of the second calculation period in the second display target area 607. Are shifted in the order of the first history area 607c of the second calculation period→the second history area 607d of the second calculation period, the nearest area 607b of the second calculation period→the first history area 607c of the second calculation period. Thereby, the payout rate data in the second calculation period two times before the second calculation period ended this time is stored in the second history area 607d of the second calculation period, and one time before the second calculation period ended this time. The payout rate data in the second calculation period is stored in the first history area 607c in the second calculation period. In the second data shift processing, the LDIR instruction is used when the above information shift is performed. In the LDIR instruction, the information stored in the storage area is shifted (copied) to the storage area by designating the address of the storage area of the information and the address of the storage area of the information. Becomes Further, in the second data shift processing in step SL223, after the information shift processing as described above is performed, “0” is cleared in the immediate area 607b of the second calculation period.

After that, the payout rate data stored in the second unit update area 607a is stored in the area 607b closest to the second calculation period (step SL224), and this payout rate calculation processing is ended. As described above, the second unit update area 607a stores the payout rate for the last ten unit calculation periods. When the value of the second write pointer 604 makes one round and one second calculation period ends, the latest 10 unit calculation periods are the 10 unit calculation periods included in the second calculation period ended this time. For this reason, the final payout rate data in the second calculation period ended this time is stored in the second unit update area 607a, and in step SL209, the most recent area 607b of the second calculation period also ends this time. The final payout rate data for the two calculation periods is stored.

Returning to the explanation of the check processing (FIG. 325), after executing the payout rate storage processing in step SL112, by executing the clear processing of the incoming ball number counter area 596, various counters 596a in the incoming ball number counter area 596. The value of ˜596e is cleared to “0” (step SL113).

If a negative determination is made in step SL107, the process of step SL109 is performed, a negative determination is made in step SL111, or the process of step SL113 is performed, the display process is executed. (Step SL114), this check processing is ended.

FIG. 327 is a flowchart showing the display processing. The processes of steps SL301 to SL314 in the display process are executed using the non-specific control program and the non-specific control data in the main CPU 63.

In the display process, it is first determined whether or not the first notification start flag 608 in the work area 223 for non-specific control is set to "1" (step SL301). When a positive determination is made in step SL301, the value of the display switching counter provided in the work area 223 for non-specific control is decremented by 1 (step SL302). The display switching counter is a display device for the first to fifth notifications among the payout rates stored in the various areas 606a to 606d of the first display target area 606 and the various areas 607a to 607d of the second display target area 607. This is a counter for the main CPU 63 to specify that it is the timing to switch the payout rate to be notified in 591 to 595. In the first to fifth notification display devices 591 to 595, when “1” is set in the first notification start flag 608 and the second notification start flag 609, the display continuation period (specifically, 5 seconds) is set. Every time the time elapses, the first unit update area 606a→the latest area 606b of the first calculation period→the first history area 606c of the first calculation period→the second history area 606d of the first calculation period→the second unit update area 607a→ The payout rate to be notified is switched in a predetermined order of the latest area 607b of the second calculation period→the first history area 607c of the second calculation period→the second history area 607d of the second calculation period, and Switching of the payout rate to be notified is repeated in a predetermined order. Further, in the first to fifth notification display devices 591 to 595, when the first notification start flag 608 is set to "1" and the second notification start flag 609 is not set to "1", the display is performed. Every time the continuation period (specifically, 5 seconds) elapses, the first unit update area 606a→the closest area 606b of the first calculation period→the first history area 606c of the first calculation period→the second of the first calculation period The payout rate to be notified is switched in a predetermined order in the history area 606d, and the switching of the payout rate to be notified is repeated in the predetermined order.

After that, it is determined whether or not the display continuation period has elapsed after the current payout rate, which is the notification target, becomes the notification target (step SL303). In step SL303, it is determined that the display continuation period has elapsed when the value of the switching timing counter after subtracting 1 in step SL302 is "0". When an affirmative determination is made in step SL303, it is determined whether or not "1" is set in the second notification start flag 609 (step SL304). When a negative determination is made in step SL304, the first update process of the notification target counter is executed (step SL305). In the first update processing, 1 is added to the value of the notification target counter provided in the work area 223 for non-specific control. Then, when the value of the notification target counter after adding 1 exceeds the first maximum value “3” (step SL306: YES), the value of the notification target counter is cleared to “0” (step SL307).

The notification target counter is a display device for the first to fifth notifications among the payout rates stored in each of the various areas 606a to 606d of the first display target area 606 and each of the areas 607a to 607d of the second display target area 607. This is a counter for the main CPU 63 to specify the payout rate to be notified in 591 to 595. When the first notification start flag 608 is set to "1" and the second notification start flag 609 is not set to "1", the notification target counter adds 1 to the previous value each time it is updated, 1 After reaching the maximum value of "3", the value returns to "0". When the value of the notification target counter is “0”, the payout rate stored in the first unit update area 606a is the notification target, and when the value of the notification target counter is “1”, the first calculation period The payout rate stored in the latest area 606b is the notification target, and when the value of the notification target counter is “2”, the payout rate stored in the first history area 606c of the first calculation period is the notification target. When the value of the notification target counter is “3”, the payout rate stored in the second history area 606d of the first calculation period is the notification target. Further, when the value of the notification target counter is "4", the payout rate stored in the second unit update area 607a becomes the notification target, and when the value of the notification target counter is "5", the second The payout rate stored in the area 607b closest to the calculation period is the notification target, and when the value of the notification target counter is "6", the payout rate stored in the first history area 607c of the third calculation period is When the value of the notification target counter is “7”, the payout rate stored in the second history area 607d of the second calculation period becomes the notification target.

Therefore, when the first notification start flag 608 is set to "1" and the second notification start flag 609 is not set to "1", the first unit update area 606a and the first calculation period The payout rate stored in the latest area 606b, the first history area 606c of the first calculation period, and the second history area 606d of the first calculation period is the notification target.

On the other hand, if an affirmative determination is made in step SL304, the second update process of the notification target counter is executed (step SL308). In the second update processing, 1 is added to the value of the notification target counter provided in the work area 223 for non-specific control. Then, when the value of the notification target counter after adding 1 exceeds the second maximum value of "7" (step SL309: YES), the value of the notification target counter is cleared to "0" (step SL310). When “1” is set in the first notification start flag 608 and the second notification start flag 609, the notification target counter increments the previous value by 1 each time it is updated, and sets the second maximum value to “7”. After reaching, it returns to "0".

Therefore, when “1” is set in the first notification start flag 608 and the second notification start flag 609, the first unit update area 606a, the area closest to the first calculation period 606b, and the first calculation period The first history area 606c, the second history area 606d of the first calculation period, the second unit update area 607a, the immediate area 607b of the second calculation period, the first history area 607c of the second calculation period, and the second calculation period The payout rate stored in the second history area 607d is to be notified.

When a negative determination is made in step SL306, the process of step SL307 is executed, a negative determination is made in step SL309, or the process of step SL310 is performed, the work area 223 for non-specific control is provided. A value corresponding to the display continuation period (specifically, 5 seconds) is set as the value corresponding to the switching timing of the next notification target in the display switching counter of (step SL311).

When a negative determination is made in step SL303, or when the process of step SL311 is executed, the display target setting area 276 in the work area 223 for non-specific control corresponds to the payout rate which is the notification target of this time. The processing for setting the display data to be performed (the processing of step SL312 and step SL313) is executed. As described above, display data including display type data and payout rate display data is set in the display target setting area 276.

Specifically, first, display type data corresponding to the value of the notification target counter is set in the display target setting area 276 (step SL312). As described above, the display type data includes a display (display of characters “d” or “d.”) indicating that the notification target of the first to fifth notification display devices 591 to 595 is the payout rate. The display data to be displayed on the first notification display device 591 and the payout rate of the notification target among the various areas 606a to 606d of the first display target area 606 and the various areas 607a to 607d of the second display target area 607. Display data for causing the second notification display device 592 to perform a display (display of any one of the characters "A", "L", "F", and "E") indicating which one corresponds. Including and

After that, the payout rate data is read from the area corresponding to the value of the notification target counter among the various areas 606a to 606d of the first display target area 606 and the various areas 607a to 607d of the second display target area 607, and the read output is performed. The payout rate display data corresponding to the ball rate data is set in the display target setting area 276 (step SL313), and the main display processing is ended. The payout rate display data is display data for causing the third notification display device 593 to perform a display corresponding to the hundreds digit in the payout rate of the notification target, and a tens digit in the payout rate of the notification target. Display data for causing the fourth notification display device 594 to perform a display corresponding to the number, and a display corresponding to the first digit in the payout rate of the notification target to the fifth notification display device 595. And display data for.

The display data including the display type data and the payout rate display data set in the display target setting area 276 in steps SL312 and SL313 is transmitted to the display IC 266, whereby the first to fifth notification display devices 591. At ~595, the payout rate corresponding to the display data is displayed.

The process of step SL313 is executed every time the display process (FIG. 327) is executed regardless of the timing of switching the payout rate of the notification target. As described above, the first unit update area 606a and the second unit update area 607a are updated every time the unit calculation period ends. The latest area 606b of the first calculation period, the first history area 606c of the first calculation period, and the second history area 606d of the first calculation period are updated each time the first calculation period ends, and the second calculation is performed. The latest area 607b of the period, the first history area 607c of the second calculation period, and the second history area 607d of the second calculation period are updated each time the second calculation period ends. In this case, the processing of step SL313 for setting the payout rate display data in the display target setting area 276 as described above is executed regardless of the timing of switching the payout rate of the notification target (FIG. 327). When the payout rate data stored in each of the various areas 606a to 606d of the first display target area 606 is updated by being executed every time, the output after the update is performed even if the switching timing is not reached. It becomes possible to notify the ball rate, and when the ball output rate data stored in the various areas 607a to 607d of the second display target area 607 is updated, even if the switching timing does not come, the update is performed. It is possible to inform the ball output rate of.

On the other hand, if "1" is not set in the first notification start flag 608 provided in the work area 223 for non-specific control and a negative determination is made in step SL301, the current status is present regardless of the value of the notification target counter. The current payout rate data stored in the payout rate area 599 is read out, and the payout rate corresponding to the hundreds digit, the tens digit and the ones digit in the read-out payout rate data. The display data is set in the display target setting area 276 (step SL314), and the display processing is ended. By transmitting display data corresponding to the payout rate display data to the display IC 266, the hundreds digit in the current payout rate data stored in the current payout rate area 599 is displayed for the third notification. Displayed by the device 593, the tens digit in the current payout rate data is displayed by the fourth notification display device 594, and the ones digit in the current payout rate data is displayed by the fifth notification. It is displayed on the device 595. With the above configuration, in a situation where “1” is not set in the first notification start flag 608, the payout rate in the past unit calculation period, the first calculation period and the second calculation period is not notified. Only the current payout rate in the current payout rate area 599 is notified.

When "1" is not set in the first notification start flag 608, the output rate display data is set in the display target setting area 276, but the display type data is not set. When the payout rate is notified in a situation where "1" is not set in the first notification start flag 608, the display contents of the first notification display device 591 and the second notification display device 592 are the first The display content is different from that when the notification of the payout rate is performed in the situation where the notification start flag 608 is set to "1". The details of the display contents of the first notification display device 591 and the second notification display device 592 in a situation where “1” is not set in the first notification start flag 608 will be described later.

Next, the normal setting process executed by the main CPU 63 will be described with reference to the flowchart in FIG. The normal setting process is executed in step S9007 of the second timer interrupt process (FIG. 134). Further, the processes of step SL401 to step SL409 in the normal setting process are executed by the main CPU 63 using the specific control program and the specific control data.

In Step SL401 to Step SL402, the same processing as Step S9101 to Step S9102 of the setting processing (Fig. 135) in the normal time in the 35th embodiment is executed. Specifically, it is determined whether the value of the checking counter provided in the specific control work area 221 is 1 or more (step SL401). The in-checking counter is mainly used to perform a check display for checking whether each of the display segments 611 to 615 of the first to fifth notification display devices 591 to 595 can normally emit light. This is a counter that can be grasped by the side CPU 63. The main CPU 63 grasps that the check display is to be executed when the value of the checking counter is “1” or more. Similar to the 35th embodiment, in the checking counter setting process executed in step S8804 of the main process (FIG. 132), the checking counter corresponds to the initial check period (specifically, 5 seconds). The value is set. If the value of the checking counter is 1 or more in the checking counter updating process executed in step S9002 of the second timer interrupt process (FIG. 134), the checking counter value is decremented by 1. ..

When the value of the checking counter is 1 or more (step SL401: YES), it means that it is the initial check period. In this case, the check display data is set in the fifth display data buffer 275 in the specific control work area 221 (step SL402). The display data set in the fifth display data buffer 275 is display data for controlling the display of the first to fifth notification display devices 591 to 595, as described above. The check display data is display data for performing the check display on the first to fifth notification display devices 591 to 595, that is, on each of the first to fifth notification display devices 591 to 595. The display data is for displaying all the display segments 611 to 615 in a light emitting state. By supplying the data for the check display to the display IC 266, all the display segments 611 to 615 in the first to fifth notification display devices 591 to 595 are turned on as the check display. As a result, the manager of the game hall can understand whether or not the display segments 611 to 615 of the first to fifth notification display devices 591 to 595 can normally be in the light emitting state.

If the value of the checking counter is "0" and it is not the initial check period (step SL401: NO), "1" is set to the first notification start flag 608 provided in the work area 223 for non-specific control. It is determined whether or not there is (step SL403). When "1" is not set in the first notification start flag 608 (step SL403: NO), the initial correspondence display setting process is executed for the first and second notification display devices 591 and 592 (step SL404). In the setting process, display data for setting all the display segments 611, 612 in the first and second notification display devices 591, 592 to the light emitting state is set in the fifth display data buffer 275. The first and second notification display devices 591 and 592 are not limited to the configuration in which all the display segments 611 and 612 are in the light emitting state, and the first and second notification display devices 591 and It is also possible to adopt a configuration in which all of the display segments 611 and 612 in each of the 592 display a blinking display.

After that, the payout rate display data set in the display target setting area 276 in the work area 223 for non-specific control is read (step SL405), and the read-out payout rate display data is used for the third to fifth notification display devices. It is set in the fifth display data buffer 275 as display data to be applied to 593 to 595 (step SL406). As described above, in the display process (FIG. 327), when “1” is not set in the first notification start flag 608 (step SL301: NO), the current payout rate data is read from the current payout rate area 599. Then, the payout rate display data corresponding to the hundreds digit, the tens digit and the ones digit in the read current payout rate data is set in the display target setting area 276 (step SL314). In step SL406, the payout rate display data is set in the fifth display data buffer 275 as display data to be applied to the third to fifth notification display devices 593 to 595.

The display data set in the fifth display data buffer 275 in steps SL404 and SL406 is supplied to the display IC 266, whereby all the display segments 611 in each of the first and second notification display devices 591 and 592. , 612 are in a light emitting state, the hundredth digit of the current payout rate data stored in the current payout rate area 599 is displayed on the third notification display device 593, and the fourth digit is displayed. The tens digit of the current payout rate data is displayed on the notification display device 594, and the ones digit of the current payout rate data is displayed on the fifth notification display device 595. In each of the first and second notification display devices 591 and 592, the numbers corresponding to the payout rate are displayed on the third to fifth notification display devices 593 to 595 while all the display segments 611 and 612 are in the light emitting state. By displaying, the game hall manager can be made aware that the current payout rate is the current payout rate in a situation where the first notification start flag 608 is not set to "1". It will be possible.

Further, in the situation where the first notification start flag 608 and the second notification start flag 609 are set to “1”, as described above, every time the display continuation period (specifically, 5 seconds) elapses, 1 unit update area 606a→closest area 606b of the first calculation period→first history area 606c of the first calculation period→second history area 606d of the first calculation period→second unit update area 607a→closest of the second calculation period Area 607b → the first history area 607c of the second calculation period → the second history area 607d of the second calculation period, the ball output rate to be notified is switched in a predetermined order, whereas the first notification start In the situation where “1” is not set in the flag 608, the current payout rate in the current payout rate area 599 is maintained as the notification target. Accordingly, when the operation check of the pachinko machine 10 is performed at the shipping stage of the pachinko machine 10, it is possible to check the current payout rate at any timing. In addition, even after the calculation start flag 597 is set to "1", it is possible to confirm the current payout rate in a situation where the payout rate is not stored once in the first display target area 606. Become.

Then, it is determined whether or not “1” is set in the calculation start flag 597 provided in the work area 223 for non-specific control (step SL407). As described above, the calculation start flag 597 has a value of “0” when the supply of operating power to the pachinko machine 10 is started for the first time after the pachinko machine 10 is manufactured. The value of the calculation start flag 597 also becomes “0” when the work area 223 for non-specific control including the calculation start flag 597 is cleared to “0” and initialized. Then, when the calculation start flag 597 has a value of “0”, the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) is the calculation start reference number (specifically, However, the calculation start flag 597 is set to “1”. When the calculation start flag 597 is not set to "1" (step SL407: NO), the blinking setting process of the first and second notification display devices 591 and 592 is executed (step SL408), and the normal operation is performed. The time setting process ends.

In the blinking setting process of the first and second notification display devices 591 and 592 in step SL408, the display corresponding to the display data currently set in the fifth display data buffer 275 is displayed in the first and second notification display devices 591. , 592, the setting is made so that the display blinks. As the setting for making the display blinking, specifically, regarding the transmission of the display data to the first and second notification display devices 591 and 592, the display data currently set in the fifth display data buffer 275 is set. Corresponding data is transmitted to the display IC 266 until a predetermined lighting period (for example, 0.5 seconds) elapses, and then all the display segments 611 and 612 of the first and second notification display devices 591 and 592 are turned off. The state data is transmitted to the display IC 266 until a predetermined extinguishing period (for example, 0.5 seconds) elapses, and thereafter, the predetermined lighting period and the predetermined extinguishing period are alternately repeated. As a result, when the payout rate is displayed in a situation where "1" is not set in the calculation start flag 597, blinking display is performed on the first and second notification display devices 591 and 592. It is possible to comprehend that the total number of game balls discharged from the game area PA does not reach the calculation start reference number (specifically, 300) based on the blinking display.

When it is determined in step SL403 that the first notification start flag 608 is set to "1", the display data set in the display target setting area 276 in the work area 223 for non-specific control is read, and the read display is performed. The data is set in the fifth display data buffer 275 (step SL409), and the setting process at the normal time is ended. By supplying the display data to the display IC 266, the display corresponding to the payout rate that is the notification target is performed on the first to fifth notification display devices 591 to 595. As described above, when “1” is not set in the second notification start flag 609, the first unit update area 606a→first unit is updated every time the display continuation period (specifically, 5 seconds) elapses. In the predetermined order of the nearest area 606b of the calculation period→the first history area 606c of the first calculation period→the second history area 606d of the first calculation period, in the first to fifth notification display devices 591-595, The payout rate stored in the various areas 606a to 606d of the first display target area 606 can be grasped. When the second notification start flag 609 is set to "1", the first unit update area 606a → the first calculation period is changed every time the display continuation period (specifically, 5 seconds) elapses. Nearest area 606b→first history area 606c of first calculation period→second history area 606d of first calculation period→second unit update area 607a→nearest area 607b of second calculation period→first history of second calculation period Areas 607c→second history area 607d of the second calculation period, in the predetermined order, in the first to fifth notification display devices 591 to 595, various areas 606a to 606d of the first display target area 606, and 2 It is possible to grasp the payout rate stored in the various areas 607a to 607d of the display target area 607.

Next, how the first notification start flag 608 and the second notification start flag 609 are set to “1” will be described with reference to the time chart of FIG. 329. FIG. 329(a) shows the state of the first notification start flag 608, FIG. 329(b) shows the update timing of the first display target area 606, and FIG. 329(c) shows the end timing of the first first calculation period. 329(d) shows the state of the second notification start flag 609, FIG. 329(e) shows the update timing of the second display target area 607, and FIG. 329(f) shows the first second calculation period. 329 (g) shows the period in which the initial correspondence display is performed on the first and second notification display devices 591 and 592, and FIG. 329 (h) shows the first and second notification display devices. 591(592) shows the period in which blinking is displayed, FIG. 329(i) shows the state of the calculation start flag 597, FIG. 329(j) shows the initial check period, and FIG. 329(k) shows the first unit calculation. The start timing of the period is shown.

At the timing of t1, the initial check period starts as shown in FIG. 329(j). As a result, the check display is started on the first to fifth notification display devices 591 to 595. Then, at the timing of t2, the initial check period ends as shown in FIG. 329(j). As a result, the check display is completed on the first to fifth notification display devices 591 to 595. At the timing t2 when the initial check period ends, the initial correspondence display is started on the first and second notification display devices 591 and 592 as shown in FIG. 329(g). As described above, the character "8.8" is displayed on the first and second notification display devices 591 and 592 in the initial correspondence display. Further, at the timing of t2, as shown in FIG. 329(h), the blinking display period in the first and second notification display devices 591, 592 is started. Therefore, on the first and second notification display devices 591 and 592, the character "8.8" is displayed in a blinking manner from the timing t2 to the timing t3.

Thereafter, at the timing of t3, "1" is set to the calculation start flag 597 as shown in FIG. 329(i). As described above, in the calculation start flag 597, the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) in the entire game state is the calculation start reference number ( "1" is set when the number becomes 300). At the timing of t3, as shown in FIG. 329(k), the first unit calculation period is started. Further, as shown in the timing chart 329(h) at t3, the blinking display period in the first and second notification display devices 591, 592 ends. As a result, the characters “8.8” are lit and displayed on the first and second notification display devices 591 and 592.

Then, when the first first calculation period ends as shown in FIG. 329(c) at the timing of t4, the first display target area 606 is updated as shown in FIG. 329(b). Specifically, the first unit update area 606a stores the payout rate data for the entire unit calculation period for the latest four times. At the timing of t4 when the first calculation period ends, the 0th to 3rd storage areas 601a to 601d of the first management buffer 601 have four outputs in each of the latest four unit calculation periods included in the first calculation period. Stores the ball rate data. Therefore, the payout rate data in the entire unit calculation period for the latest four times stored in the first unit update area 606a at the timing of t4 is the final payout rate data in the first calculation period ended this time. Further, at the timing of t4, the final payout rate data in the first calculation period is also stored in the area 606b closest to the first calculation period. Further, at the timing of t4, as shown in FIG. 329(g), the initial correspondence display on the first and second notification display devices 591, 592 ends, and as shown in FIG. 329(a), the first notification start flag. “1” is set in 608. As a result, the first to fifth notification display devices 591 to 595 start displaying the payout rates stored in the various areas 606a to 606d of the first display target area 606.

Then, when the first second calculation period ends as shown in FIG. 329(f) at the timing of t5, the second display target area 607 is updated as shown in FIG. 329(e). Specifically, in the second unit update area 607a, the payout rate data for the entire last 10 unit calculation periods is stored. At the timing of t5 when the second calculation period ends, the 0th to 9th storage areas 602a to 602j of the second management buffer 602 have 10 outputs in each of the last 10 unit calculation periods included in the second calculation period. Stores the ball rate data. For this reason, at the timing of t5, the payout rate in the entire unit calculation period for the last 10 times stored in the second unit update area 607a is the final payout rate data in the second calculation period which has ended this time. Further, at the timing of t5, the final payout rate data in the second calculation period is also stored in the area 607b closest to the second calculation period. Further, at the timing of t5, "1" is set to the second notification start flag 609 as shown in FIG. 329(d). As a result, in addition to displaying the payout rate stored in the various areas 606a to 606d of the first display target area 606 on the first to fifth notification display devices 591 to 595, the second display target area 607 is displayed. The display of the payout rate stored in the various areas 607a to 607d is started.

As described above, until the timing t4 when the first notification start flag 608 is set to "1", the initial correspondence display is performed on the first and second notification display devices 591 and 592, and the first to the first notifications are performed. The display device 591 to 595 for 5 notification displays the current payout rate in the current payout rate area 599. Therefore, the manager of the game hall determines that the first to fifth notification display devices 591 are based on the characters "8.8" being displayed on the first and second notification display devices 591 and 592. It is possible to understand that the current payout rate in the current payout rate area 599 is displayed from No. 595 to No. 595.

Until the timing of t4 when the first notification start flag 608 is set to "1", the various areas 606a to 606d of the first display target area 606 and the various areas 607a to 607d of the second display target area 607 are the first to first areas. 5 Display devices for notification 591 to 595 are not displayed. As a result, the various areas 606a to 606d of the first display target area 606 and the various areas 607a to 607d of the second display target area 607 in the state where the payout rate data is not stored are the third to fifth areas. It is prevented that the payout rate of “000” is continuously displayed on the notification display devices 593 to 595.

In the period from timing t4 to timing t5 in which the first notification start flag 608 is set to "1" and the second notification start flag 609 is not set to "1", the first to fifth notification displays are displayed. In the devices 591 to 595, the various areas 606a to 606d of the first display target area 606 are display targets, whereas the various areas 607a to 607d of the second display target area 607 are not display targets. As a result, the various areas 607a to 607d of the second display target area 607 in which the payout rate data is not stored become display targets, and "000" is displayed on the third to fifth notification display devices 593 to 595. It is prevented that the ball rate is displayed continuously.

According to this embodiment described in detail above, the following excellent effects are exhibited.

In the first to fifth notification display devices 591 to 595, display of the payout rate showing the ratio of the total payout number of the game balls to the total number of the game balls discharged from the game area PA of the pachinko machine 10 in all the game states. Is done. From this, it is understood that various ball output rates are in an abnormal state that exceeds the upper limit of the normal range (first normal range and second normal range), and that various ball output rates are in an abnormal state that is below the lower limit of the normal range. It can be possible. By confirming that the various payout rates are in an abnormal state that exceeds the upper limit of the normal range, it is possible to confirm with the manager of the game hall whether there is an act that illegally increases the total payout number of game balls. You can give an opportunity to do. Further, by making it possible to grasp that the various ball output rates are in an abnormal state below the lower limit of the normal range, the nail 24b scolded on the game board 24 of the pachinko machine 10 can be grasped by the manager of the game hall. It is possible to give an opportunity to perform maintenance for adjusting the state and the like.

The first to fifth notification display devices 591 to 595 are configured to display various payout rates in the numerical range of "0" to "999", so that the various payout rates are within the normal range (first 1 normal range and 2nd normal range) If the lower limit (41% in the 1st normal range, 51% in the 2nd normal range) is below, there is only the presence or absence of an abnormality in which the payout rate falls below the lower limit of the normal range. Instead, it is possible to understand the extent of the abnormality. Specifically, it is possible to understand that the lower the payout rate is, the more serious the anomaly is and the quick response is required. In addition, if the various payout rates exceed the upper limit of the normal range (149% in the first normal range, 133% in the second normal range), only the presence or absence of an abnormality in which the payout rate exceeds the upper limit of the normal range Instead, it is possible to understand the extent of the abnormality. Specifically, it is possible to understand that the higher the payout rate is, the more serious the anomaly is and the quick response is required.

Various payout rates are calculated without distinguishing the game state. Specifically, the various payout rates are the respective ball entry portions in the gaming state that is neither the opening/closing execution mode nor the high frequency support mode, the gaming state that is the opening/closing execution mode, and the gaming state that is the high frequency support mode. It is calculated based on the number of incoming balls to 24a, 31 to 34. For this reason, it is not necessary to provide a counter for counting the number of balls entering each of the ball-in portions 24a, 31 to 34 for each game state, and the presence or absence of abnormality in various ball-out rates for all game states and the abnormality. The degree can be grasped. As a result, it is possible to reduce the storage capacity in the main RAM 65 for grasping the presence/absence and the degree of abnormality of various payout rates in all gaming states.

Every time the unit calculation period ends, the payout rate in the unit calculation period is calculated within a numerical range of “0” to “999”, and the calculated payout rate information (ball payout rate data) is stored in the first management buffer. The storage areas 601a to 601d of 601 and the storage areas 602a to 602j of the second management buffer 602 are configured to be stored. The storage area 601a to 601d of the first management buffer 601 and the second management are configured by storing the information on the payout rate, which has a data amount smaller than the data amount of the information on the final total payout number in the unit calculation period. It is possible to reduce the storage capacity of the storage areas 602a to 602j of the buffer 602.

The first unit update area 606a stores the payout rate data for the entire unit calculation period for the last four times. The first unit update area 606a is updated every time the unit calculation period ends even during the first calculation period. By displaying the payout rate of the first unit update area 606a on the first to fifth notification display devices 591 to 595, an abnormality of the payout rate with respect to the first normal range (41% to 149%) occurs. In this case, the abnormality can be grasped at an early stage. Further, the second unit update area 607a stores the payout rate data for the entire unit calculation period for the last 10 times. The second unit update area 607a is updated every time the unit calculation period ends, even during the second calculation period. By displaying the payout rate of the second unit update area 607a on the first to fifth notification display devices 591 to 595, an abnormality of the payout rate with respect to the second normal range (51% to 133%) occurs. In this case, the abnormality can be grasped at an early stage.

Based on the payout rate data stored in the first display target area 606 and the second display target area 607, the payout rate in the entire unit calculation period for four times on the first to fifth notification display devices 591 to 595. (The payout rate in the entire unit calculation period for the last 4 times and the payout rate in the first calculation period) and the payout rate in the entire unit calculation period for the latest 10 times (the payout rate in the entire unit calculation period for the latest 10 times and The payout rate in the second calculation period) is displayed. The lower limit (41%) of the first normal range (41% to 149%) is set smaller than the lower limit (51%) of the second normal range (51% to 133%), and the upper limit of the first normal range is set. (149%) is set to be larger than the upper limit (133%) of the second normal range. Therefore, even when the payout rate in the entire unit calculation period for 10 times is out of the second normal range, the payout rate in the entire unit calculation period for 4 times remains within the first normal range. There are cases. In addition, when an abnormality in which the payout rate is out of the normal numerical range occurs temporarily, the payout rate in the entire unit calculation period for four times is out of the first normal range, while the entire unit calculation period for ten times is complete. It is conceivable that the payout rate in 1 may fall within the second normal range. On the other hand, in the present embodiment, the first to fifth notification display devices 591 to 595 display both the payout rate in the entire unit calculation period for four times and the payout rate in the entire unit calculation period for ten times. With such a configuration, it is possible to prevent the abnormality of the payout rate in the entire unit calculation period for four times and the abnormality of the payout rate in the entire unit calculation period for ten times from being overlooked.

Each time the unit calculation period ends, the payout rate in the entire last four unit calculation periods is calculated based on the payout rate data stored in the first management buffer 601. In the above configuration, when one first calculation period ends due to the end of the unit calculation period, the payout rate in the entire unit calculation period for the last four times is the final payout in the first calculation period ended this time. It becomes a ball rate. Therefore, a buffer for storing information (ball-out rate data in the unit-calculation period) for calculating the ball-out rate in the entire unit calculation period for the last four times and a final ball-out rate in the first calculation period are calculated. In comparison with the configuration in which a buffer for storing information (ball output rate data in the unit calculation period) is separately provided, the ball output rate in the entire unit calculation period for the last four times and the final in the first calculation period It is possible to reduce the storage capacity in the main RAM 65 for storing the information for calculating the effective payout rate.

Each time the unit calculation period ends, the payout rate in the entire last 10 unit calculation periods is calculated based on the payout rate data stored in the second management buffer 602. In the configuration, when one second calculation period ends due to the end of the unit calculation period, the payout rate in the entire unit calculation period for the last 10 times is the final payout in the second calculation period ended this time. It becomes a ball rate. Therefore, a buffer for storing information (ball-out rate data in the unit-calculation period) for calculating the ball-out rate in the entire last ten unit-calculation periods and a final ball-out rate in the second calculation period are calculated. In comparison with a configuration in which a buffer for storing information (ball output rate data in the unit calculation period) is separately provided, the ball output rate in the entire unit calculation period for the last 10 times and the final in the second calculation period It is possible to reduce the storage capacity in the main RAM 65 for storing the information for calculating the effective payout rate.

In the first to fifth notification display devices 591 to 595, in addition to the display of the payout rate in the latest first calculation period, the display of the payout rate in the first calculation period immediately before and the second time before the second calculation period. The payout rate in one calculation period is displayed. By displaying whether or not the payout rate in the past first calculation period is within the first normal range (41% to 149%), it is possible to display the first to fifth notification display devices 591 to 595. It is possible to reduce the frequency of checking and reduce the monitoring load on the manager of the game hall. Further, when an abnormality in the payout rate in the latest first calculation period is confirmed, it is possible to trace back from a time when the abnormality in the payout rate has occurred.

In the first to fifth notification display devices 591 to 595, in addition to the display of the payout rate in the latest second calculation period, the display of the payout rate in the second calculation period immediately before and the second time before the second calculation period. 2 The payout rate in the calculation period is displayed. By displaying whether or not the payout rate in the past second calculation period is within the second normal range (51% to 133%), it is possible to display the first to fifth notification display devices 591 to 595. It is possible to reduce the frequency of checking and reduce the monitoring burden on the manager of the game hall. Further, when an abnormality in the payout rate in the latest second calculation period is confirmed, it is possible to trace back from a time when the abnormality in the payout rate has occurred.

This is a configuration in which a plurality of types of payout rates are displayed on the first to fifth notification display devices 591 to 595. Specifically, when the first notification start flag 608 is set to “1” and the second notification start flag 609 is not set to “1”, the first to fifth notification display devices 591 to 595 are provided. Then, the payout rates of the various areas 606a to 606d of the first display target area 606 are displayed. Further, when “1” is set in the first notification start flag 608 and the second notification start flag 609, in the first to fifth notification display devices 591 to 595, various areas 606a of the first display target area 606 are displayed. To 606d and various areas 607a to 607d of the second display target area 607 are displayed. In this configuration, the display of these payout rates is automatically switched every time a predetermined display period (specifically, 5 seconds) ends. As a result, the number of operations required to display the type of payout rate to be confirmed can be reduced, and the burden on the manager of the game hall can be reduced.

On the first and second notification display devices 591 and 592, a display indicating the type of payout rate displayed on the first to fifth notification display devices 591 to 595 is performed. The first normal range (41% to 149%), which is the normal range of the payout rate for the entire unit calculation period for four times, and the second normal range (the normal range for the payout rate for the entire unit calculation period for ten times ( 51% to 133%). Therefore, when the type of the payout rate displayed on the first to fifth notification display devices 591 to 595 is erroneously recognized, the payout rate is within the normal range (first normal range or second normal range). There is a possibility that the judgment of whether or not it is within is erroneous. The combination of the display on the first notification display device 591 and the display on the second notification display device 592 indicates the type of the payout rate displayed on the first to fifth notification display devices 591 to 595. By making it possible to grasp, in the configuration in which the first to fifth notification display devices 591 to 595 display a plurality of types of payout rates, misidentification of the types of the payout rates is prevented, and It is possible to accurately determine whether the ball rate is within the normal range (first normal range or second normal range).

On the third to fifth notification display devices 593 to 595, the hundreds digit of the payout rate, the tenth digit of the payout rate, and the ones digit of the payout rate are displayed. By making it possible to grasp the payout rate as three-digit numerical information (“0” to “999”) on the first to fifth notification display devices 591 to 595, the normal range (first normal range or second range) It is possible to grasp not only whether or not there is an abnormality in the payout rate for the normal range), but also the degree of the abnormality.

Since the first management buffer 601 and the second management buffer 602 that store the payout rate data in the unit calculation period are ring buffers, it is possible to move the already-stored payout rate data in the past unit calculation period. Instead, the payout rate data in the unit calculation period ended this time can be newly stored in these management buffers 601 and 602. This simplifies the processing configuration for storing a plurality of payout rate data in each unit calculation period for the latest multiple times, and stores a plurality of payout rate data in each unit calculation period for the latest multiple times. It is possible to reduce the processing load for doing so.

The main CPU 63 recognizes that the first calculation period has ended based on that the value of the first write pointer 603 that enables the write destination in the first management buffer 601 to make one round. Therefore, a main counter for grasping the end timing of the first calculation period is compared with a configuration in which a dedicated counter for grasping the end timing of the first calculation period is provided separately from the first write pointer 603. The storage capacity in the side RAM 65 can be reduced, and the processing configuration for grasping the end timing of the first calculation period can be simplified. Further, the main CPU 63 recognizes that the second calculation period has ended based on the value of the second write pointer 604 that enables the write destination in the second management buffer 602 to make one round. Therefore, as compared with the configuration in which a dedicated counter for grasping the end timing of the second calculation period is provided separately from the second write pointer 604, a main counter for grasping the end timing of the second calculation period is provided. The storage capacity in the side RAM 65 can be reduced, and the processing configuration for grasping the end timing of the second calculation period can be simplified.

In a situation where "1" is not set in the first notification start flag 608, various areas 606a to 606d of the first display target area 606 and the second display target area in the first to fifth notification display devices 591 to 595. The payout rate is not displayed in the various areas 607a to 607d of 607. As a result, the various areas 606a to 606d of the first display target area 606 and the various areas 607a to 607d of the second display target area 607 in the state in which the payout rate data is not stored are the display targets, and the third to fifth notifications. It is possible to prevent a situation in which the payout rate of “000” is continuously displayed on the display devices 593 to 595 for use.

When "1" is not set in the first notification start flag 608, the current payout rate in the current payout rate area 599 is displayed on the first to fifth notification display devices 591 to 595. Thereby, the current payout rate is grasped on the first to fifth notification display devices 591 to 595 until the payout rate data in the first first calculation period is stored in the first display target area 606. It can be possible.

When "1" is not set in the first notification start flag 608, the initial correspondence display is performed on the first and second notification display devices 591 and 592. Accordingly, it is possible to understand that the current payout rate is displayed in the current payout rate area 599 on the first to fifth notification display devices 591 to 595.

When the calculation start flag 597 is not set to "1", a blinking display for blinking the initial correspondence display (display of "8.8") performed on the first and second notification display devices 591 and 592 is displayed. Done. As a result, the total number of game balls discharged from the game area PA has reached the calculation start reference number (specifically 300) based on the display modes of the first and second notification display devices 591 and 592. It is possible to understand that there is no situation.

In a situation where the first notification start flag 608 is set to “1” and the second notification start flag 609 is not set to “1”, the second to fifth notification display devices 591 to 595 are used. The payout rate in the various areas 607a to 607d of the display target area 607 is not displayed. As a result, the various areas 607a to 607d of the second display target area 607 in which the payout rate data is not stored become display targets, and the display of "000" on the third to fifth notification display devices 593 to 595. It is possible to prevent the situation where the ball rate is continuously displayed.

<90th Embodiment>
In the present embodiment, the payout rate in the entire unit calculation period for the last four times, the payout rate in the first calculation period, and the unit for the latest ten times are calculated based on the payout rate data in the unit calculation period stored in the common buffer. This is different from the 89th embodiment in that the payout rate in the entire calculation period and the payout rate in the second calculation period are calculated. The structure different from that of the 89th embodiment will be described below. The description of the same configuration as the 89th embodiment is basically omitted.

FIG. 330 is an explanatory diagram for explaining various areas of the non-specific control work area 223 used for managing the game history in the embodiment.

In the work area 223 for non-specific control, a common management buffer 616 is provided as shown in FIG. 330 instead of the first management buffer 601 and the second management buffer 602 in the 89th embodiment. The common management buffer 616 stores the payout rate in the entire unit calculation period for four times (the payout rate in the entire unit calculation period for the last four times and the payout rate in the first calculation period) and for the entire unit calculation period for ten times. Information for calculating the payout rate (the payout rate in the entire unit calculation period for the last 10 times and the payout rate in the second calculation period) (specifically, 10 pieces in each unit calculation period for the latest 10 times) This is a ring buffer in which the ball output data) is stored. The common management buffer 616 is provided with 0th storage area 616a to 9th storage area 616j as storage areas for storing the payout rate data in the unit calculation period. The 0th to 9th storage areas 616a to 616j all have the same storage capacity, and specifically, it is possible to store information on the payout rate (numerical information of any one of "0" to "999"). Therefore, the storage capacity is 10 bits.

As shown in FIG. 330, a common write pointer 617 is provided in the work area 223 for non-specific control. The common write pointer 617 is a counter for allowing the main CPU 63 to grasp the storage areas 616a to 616j that are the write destinations this time among the 10 storage areas 616a to 616j of the common management buffer 616. The common write pointer 617 is a loop counter in which 1 is added to the previous value each time it is updated, and after reaching the maximum value (specifically, “9”), it returns to “0”. The value of “n” of the common write pointer 617 (n is any integer from 0 to 9) corresponds to the state where the write destination is the nth storage area 616a to 616j. For example, the value "0" of the common write pointer 617 corresponds to the state where the write destination is the 0th storage area 616a, and the value "2" of the common write pointer 617 is the write destination is the second storage area 616c. It corresponds to the state that is.

Every time the unit calculation period ends, the main CPU 63 calculates the final payout rate in the ended unit calculation period based on the values stored in the various counters 596a to 596e in the incoming ball number counter area 596. To do. Then, the information of the calculated payout rate is written in the storage areas 616a to 616j of the common management buffer 616 corresponding to the value of the common write pointer 617. The value of the common write pointer 617 is incremented by 1 each time the information on the payout rate is written in the common management buffer 616. When the value after the increment of 1 exceeds the maximum value (specifically, “9”), “ 0” is cleared. For this reason, in the 0th to 9th storage areas 616a to 616j in the common management buffer 616, 10 ball output rate data in the last 10 unit calculation periods are set.

The value of the common write pointer 617 becomes “0” in one round when the payout rate data in the unit calculation period is written in the common management buffer 616 ten times. The main CPU 63 recognizes that the second calculation period has ended based on the value of the common write pointer 617 making one round to become “0”. Therefore, as compared with the configuration in which a dedicated counter for grasping the end timing of the second calculation period is provided separately from the common write pointer 617, the main side for grasping the end timing of the second calculation period. The storage capacity of the RAM 65 can be reduced.

As shown in FIG. 330, a circulation management flag 618 is provided in the work area 223 for non-specific control. The circulation management flag 618 is a flag that enables the main CPU 63 to grasp the end timing of the first calculation period by combining with the value of the common write pointer 617. The state (“0” or “1”) of the circulation management flag 618 is inverted every time the value of the common write pointer 617 makes one round and becomes “0”. The value of the common write pointer 617 alone cannot be used to grasp that four unit calculation periods have elapsed since the end of the previous first calculation period, that is, that the current first calculation period has ended. When the value of the circulation management flag 618 is “0”, the main CPU 63 ends the previous first calculation period when the value of the common write pointer 617 is “0”, “4”, or “8”. It is possible to understand that the first calculation period of this time has ended after the unit calculation period of four times has elapsed, and when the value of the circulation management flag 618 is “1”, the value of the common write pointer 617. When is “2” or “6”, it can be understood that the unit calculation period for four times has elapsed from the end of the previous first calculation period and the current first calculation period has ended. In addition to the common write pointer 617, a 1-bit circulation management flag 618 is provided to grasp the end timing of the first calculation period, thereby providing a dedicated counter for grasping the end timing of the first calculation period. The storage capacity in the main RAM 65 for grasping the end timing of the first calculation period is reduced as compared with the configuration provided separately.

Next, the payout rate storage processing executed by the main CPU 63 will be described with reference to the flowchart in FIG. The payout rate storage process is executed in step SL112 of the check process (FIG. 325) when the unit calculation period ends. In addition, the processing from step SL501 to step SL522 in the payout rate storage processing is executed using the non-specific control program and the non-specific control data in the main CPU 63.

In the payout rate storage process, first, the current payout rate data stored in the current payout rate area 599 is grasped (step SL501). Then, based on the value of the common write pointer 617, the storage areas 616a to 616j to be the write destinations among the 0th to 9th storage areas 616a to 616j in the common management buffer 616 are specified (step SL502). As described above, when the value of the common write pointer 617 is “n” (n is any integer of 0 to 9), the nth storage areas 616a to 616j are specified as the write target storage areas 616a to 616j. It

After that, the current payout rate data grasped in step SL501 is overwritten in the storage areas 616a to 616j specified in step SL502 (step SL503), and the common write pointer 617 is updated (step SL504). In the updating process of the common write pointer 617, 1 is added to the value of the common write pointer 617, and when the value after the addition of 1 exceeds the maximum value “9”, the value of the common write pointer 617 is set to “0”. clear.

Then, in step SL504, it is determined whether or not the value of the common write pointer 617 has made one round (step SL505). In step SL505, when the value of the common write pointer 617 after being updated in step SL504 is “0”, it is determined that the value of the common write pointer 617 has made one round. If an affirmative determination is made in step SL505, the reversal processing of the circulation management flag 618 in the work area 223 for non-specific control is executed (step SL506). In the inversion process, when the value of the circulation management flag 618 is “0”, the circulation management flag 618 is set to “1”, and when the value of the circulation management flag 618 is “1”, The value of the circulation management flag 618 is cleared to "0".

Then, it is determined whether or not the first notification start flag 608 provided in the non-specific control work area 223 is set to "1" (step SL507). The first notification start flag 608 is the same as in the 89th embodiment, and displays the winning rate of various areas 606a to 606d in the first display target area 606 on the first to fifth notification display devices 591 to 595. This is a flag for the main CPU 63 to know whether or not it is in the situation of executing. The first notification start flag 608 has a value of “0” when the supply of operating power to the pachinko machine 10 is started for the first time after the pachinko machine 10 is manufactured. The value of the first notification start flag 608 is also “0” when the non-specific control work area 223 including the first notification start flag 608 is cleared and initialized to “0”. In the first notification start flag 608, “1” is set in the case where the four payout rate data in each unit calculation period for four times is stored in the storage areas 616a to 616j of the common management buffer 616. Set. The state in which the value of the first notification start flag 608 is "0" corresponds to the state in which the number of ball output rate data stored in the storage areas 616a to 616j of the common management buffer 616 is 3 or less. .. When “1” is not set in the first notification start flag 608, various areas of the first display target area 606 are displayed in the first to fifth notification display devices 591 to 595, as in the 89th embodiment. The payout rate stored in 606a to 606d is not displayed.

When a negative determination is made in step SL507, it is determined whether the value of the common write pointer 617 updated in step SL504 is "4" (step SL508). If an affirmative determination is made in step SL508, it means that the payout rate data in the unit calculation period stored in the common management buffer 616 is four, and therefore the first notification start flag 608 is set to " 1" is set (step SL509).

When an affirmative determination is made in step SL507 or when the processing of step SL509 is performed, the first payout rate calculation processing is executed (step SL510). Similar to the 89th embodiment, in the first payout rate calculation process, “1” is set in the first notification start flag 608 (a positive determination is made in step SL507, or step SL509). Is executed).

FIG. 332 is a flowchart showing the first payout rate calculation processing. Note that the processes of steps SL601 to SL609 in the first payout rate calculation process are executed using the non-specific control program and the non-specific control data in the main CPU 63.

In the first payout rate calculation processing, first, clear processing of the calculation area 598 is executed (step SL601). In the clear processing, the calculation area 598 in the work area 223 for non-specific control is cleared to "0". Then, the subtraction process of the common write pointer 617 is performed (step SL602). In the subtraction processing, the value of the common write pointer 617 in the work area 223 for non-specific control is decremented by 1. If the value of the common write pointer 617 after the decrement by 1 is less than “0”, the common write pointer 617 is set. Set "9".

After that, the value of the subtraction number counter 619 provided in the work area 223 for non-specific control is incremented by 1 (step SL603). The subtraction number counter 619 is a counter that enables the main CPU 63 to grasp the number of times the subtraction process (step SL602) of the common write pointer 617 is executed.

After that, in the common management buffer 616, the storage areas 616a to 616j corresponding to the value of the common write pointer 617 after the processing of step SL601 is grasped (step SL604), and stored in the grasped storage areas 616a to 616j. The payout rate data is added to the calculation area 598 (step SL605).

After that, it is determined whether or not the value of the subtraction number counter 619 is "4" (step SL606). If a negative determination is made in step SL606, the process returns to step SL602, and an affirmative determination is made in step SL606. The processing of step SL602 to step SL605 is repeated until it is heard. By performing the processing from step SL602 to step SL605 four times, the payout rate in the unit calculation period ended this time in the calculation area 598, the payout rate in the unit calculation period one time before, and the unit calculation two times before The payout rate in the period and the payout rate in the unit calculation period three times before are added. As a result, the total value of the four payout rates in the latest four unit calculation periods is set in the calculation area 598.

When an affirmative determination is made in step SL606, a division process of the total value is executed (step SL607). In the division processing, by dividing the total value of the latest four payout rates stored in the calculation area 598 by “4”, the payout rate in the entire unit calculation period for the latest four times is calculated, The calculated payout rate is stored in the calculation area 598. Similar to the 89th embodiment, the payout rate in the entire unit calculation period for the latest four times is calculated as 3-digit numerical information in the range of “0” to “999”. As a result, the calculation area 598 is in a state in which the ball output rate data for the entire unit calculation period for the last four times is stored.

Then, the addition processing of the common write pointer 617 is executed (step SL608). In the addition process, the value of the common write pointer 617 is incremented by 1 for four times, so that the value of the common write pointer 617 is set to a value before the first first payout rate calculation process (FIG. 322) is started. Return to. If the value of the common write pointer 617 after adding 1 exceeds the maximum value “9” of the common write pointer 617 in any of the addition processes repeated four times, the common write pointer 617 is added in the addition process. Clear the value of "0". After the value of the common write pointer 617 is cleared to "0", if the addition processing remains, the remaining addition processing is executed. After that, the value of the subtraction number counter 619 is cleared to "0" (step SL609), and the first first payout rate calculation processing is ended.

As described above, the common write pointer 617 is used to specify the storage areas 616a to 616j in the common management buffer 616 in which the four payout rate data in the latest four unit calculation periods are stored. .. As a result, compared with a configuration in which a dedicated counter for specifying the storage areas 616a to 616j is provided separately from the common write pointer 617, the four payout rate data in the latest four unit calculation periods are stored. Since the stored storage areas 616a to 616j are specified, the configuration can be simplified.

In addition, the value of the common write pointer 617 is returned to the value before the first payout rate calculation processing (FIG. 332) is started after calculating the payout rate in the entire unit calculation period for the latest four times. As a result, it is possible to prevent the writing destination in the common management buffer 616 from changing due to the first payout rate calculation processing.

Returning to the description of the payout rate storage process (FIG. 331), after executing the first payout rate calculation process (FIG. 332) at step SL510, the overwriting process of the first unit update area 606a is executed (step SL511). .. In the overwrite process, the first unit update area 606a is overwritten with the ball output rate data for the entire unit calculation period for the latest four times calculated in step SL510.

Then, it is determined whether or not it is the timing when the first calculation period ends (step SL512). In step SL512, when the value of the circulation management flag 618 is “0”, and when the value of the common write pointer 617 is “0”, “4”, or “8”, the first calculation period ends. In addition to the determination, when the value of the circulation management flag 618 is "1" and the value of the common write pointer 617 is "2" or "6", it is determined that the first calculation period has ended. When an affirmative determination is made in step SL512, the process for updating the latest area 606b of the first calculation period, the first history area 606c of the first calculation period, and the second history area 606d of the first calculation period ( The processing of steps SL513 to SL514) is executed.

In Step SL513 to Step SL514, the same processing as Step SL211 to Step SL212 of the payout rate storage processing (FIG. 326) in the 89th embodiment is executed. Specifically, first, the first data shift process is executed (step SL513). The contents of the first data shift process are as already described in the 89th embodiment. By executing the first data shift process, the payout rate data in the first calculation period that is two times before the first calculation period that has ended this time is stored in the second history area 606d of the first calculation period, and the present end The payout rate data in the first calculation period, which is one time before the first calculation period, is stored in the first history area 606c of the first calculation period, and the nearest area 606b of the first calculation period is cleared to “0”.

After that, the payout rate data stored in the first unit update area 606a is stored in the area 606b closest to the first calculation period (step SL514). As described above, the first unit update area 606a stores the payout rate for the last four unit calculation periods. The process of step SL514 is performed on condition that the timing is the end of the first calculation period (step SL512: YES). At the timing when the first calculation period ends, the latest four unit calculation periods become the unit calculation periods of four times included in the first calculation period ended this time. Therefore, at the timing when the process of step SL514 is performed, the final payout rate data in the first calculation period ended this time is stored in the first unit update area 606a, and in step SL514, the final payout rate data of the first calculation period is stored. The final payout rate data in the first calculation period ended this time is also stored in the latest area 606b.

When the negative determination is made in step SL508, the negative determination is made in step SL512, or the processing of step SL514 is performed, the second notification start flag 609 in the work area 223 for non-specific control is set. It is determined whether "1" is set (step SL515). The second notification start flag 609, similar to the 89th embodiment, displays the payout rate of each area 607a to 607d in the second display target area 607 on the first to fifth notification display devices 591 to 595. This is a flag for the main CPU 63 to know whether or not it is in the situation of executing. The second notification start flag 609 has a value of “0” when the supply of operating power to the pachinko machine 10 is started for the first time after the pachinko machine 10 is manufactured. The value of the second notification start flag 609 is also “0” when the non-specific control work area 223 including the second notification start flag 609 is cleared and initialized to “0”. In the second notification start flag 609, “1” is set in a situation where the storage area 616a to 616j of the common management buffer 616 stores 10 ball output rate data in each unit calculation period for 10 times. Set. In the state where the value of the second notification start flag 609 is “0”, the payout rate data is not stored in at least one storage area 616a to 616j of the 10 storage areas 616a to 616j of the common management buffer 616. Corresponds to the state. When "1" is not set in the second notification start flag 609, various areas of the second display target area 607 are displayed in the first to fifth notification display devices 591 to 595 as in the 89th embodiment. The payout rate stored in 607a to 607d is not displayed.

When a negative determination is made in step SL515, it is determined whether or not the value of the common write pointer 617 has made one round in the update processing of the common write pointer 617 in step SL504 (step SL516). In step SL516, when the value of the common write pointer 617 updated in step SL504 is "0", it is determined that the value of the common write pointer 617 has made one round. If the affirmative determination is made in step SL516, it means that it is the timing when the second calculation period ends, and therefore, "1" is set to the second notification start flag 609 (step SL517).

If an affirmative determination is made in step SL515, or if the processing of step SL517 is performed, the second payout rate calculation processing is executed (step SL518). In the second payout rate calculation process, first, the calculation area 598 in the work area 223 for non-specific control is cleared to "0", and the payout rate data ("" stored in the 0th storage area 616a of the common management buffer 616 Numerical information of "0" to "999") is set in the calculation area 598. After that, the sum of the 10 payout rates is calculated by adding the 9 payout rates stored in the first to ninth storage areas 616b to 616j of the common management buffer 616 to the value of the calculation area 598. Calculate the value. Then, the value in the calculation area 598 is divided by “10” to calculate the payout rate in the entire unit calculation period for the last 10 times, and the calculated payout rate is stored in the calculation area 598. As already described, the payout rate in the entire unit calculation period for the last 10 times is calculated as 3-digit numerical information in the range of “0” to “999”. As a result, the payout rate in the entire unit calculation period for the last 10 times is stored in the calculation area 598.

After that, the overwriting process of the second unit update area 607a is executed (step SL519). In the overwriting process, the second unit update area 607a is overwritten with the ball output rate data for the entire unit calculation period for the last 10 times calculated in step SL518. Similar to the 89th embodiment, the payout rate data stored in the second unit update area 607a is the payout rate data for the entire last 10 unit calculation periods each time one unit calculation period ends. Will be updated.

Then, it is determined whether it is the timing when the second calculation period ends (step SL520). In step SL520, when the value of the common write pointer 617 updated in step SL504 is “0”, it is determined that the second calculation period ends. When a negative determination is made in step SL520, the main payout rate storage processing is ended as it is.

On the other hand, if a positive determination is made in step SL520, the process proceeds to step SL521. In Step SL521 to Step SL522, the same processing as Step SL223 to Step SL224 of the payout rate storage processing (FIG. 326) in the 89th embodiment is executed. Specifically, first, the second data shift process is executed (step SL521). The content of the second data shift process is as already described in the 89th embodiment. By executing the second data shift process, the payout rate data in the second calculation period two times before the second calculation period ended this time is stored in the second history area 607d of the second calculation period, and the present end The payout rate data in the second calculation period, which is one time before the second calculation period, is stored in the first history area 607c of the second calculation period, and "0" is cleared in the nearest area 607b of the second calculation period.

After that, the payout rate data stored in the second unit update area 607a is stored in the area 607b closest to the second calculation period (step SL522), and this payout rate calculation processing is ended. As described above, the second unit update area 607a stores the payout rate for the last ten unit calculation periods. When the value of the second write pointer 604 makes one round and one second calculation period ends, the latest 10 unit calculation periods are the 10 unit calculation periods included in the second calculation period ended this time. For this reason, the final payout rate data in the second calculation period ended this time is stored in the second unit update area 607a, and in step SL522, the area close to the area 607b closest to the second calculation period in this time also ends. The final payout rate data for the two calculation periods is stored.

According to this embodiment described in detail above, the following excellent effects are exhibited.

The payout rate data in the unit calculation period is stored in the common management buffer 616, and based on the payout rate data stored in the common management buffer 616, the payout rate for the last four unit calculation periods and the last ten times are calculated. The payout rate for the entire unit calculation period is calculated. When calculating the payout rate for the last four times, and the buffer that stores the four payout rate data used when calculating the payout rate for the entire unit calculation period for the last four times Since the buffer for storing the 10 coin-out rate data to be used is common, the coin-out rate data in the unit calculation period is stored as compared with the configuration in which these buffers are separately provided. Therefore, it is possible to reduce the storage capacity of the main side RAM 65.

Using the common write pointer 617 for specifying the write destination storage areas 616a to 616j from the 0th to 9th storage areas 616a to 616j of the common management buffer 616, each of the latest four times in the common management buffer 616 is used. This is a configuration in which the storage areas 616a to 616j in which the four payout rate data in the unit calculation period are stored are specified. As a result, compared with a configuration in which a dedicated counter for specifying the storage areas 616a to 616j is provided separately from the common write pointer 617, the four payout rate data in the latest four unit calculation periods are stored. Since the stored storage areas 616a to 616j are specified, the configuration can be simplified.

This is a configuration in which after calculating the payout rate in the entire unit calculation period for the latest four times, the value of the common write pointer 617 is returned to the value before the first payout rate calculation processing (FIG. 332) is started. As a result, it is possible to prevent the writing destination in the common management buffer 616 from changing due to the first payout rate calculation processing.

The main CPU 63 ends one first calculation period when the value of the common write pointer 617 is “0”, “4”, or “8” when the value of the circulation management flag 618 is “0”. In addition to grasping the above, when the value of the circulation management flag 618 is "1" and one of the common write pointers 617 is "2" or "6", one first calculation period has ended. Figure out. In addition to the common write pointer 617, a 1-bit circulation management flag 618 is provided to grasp the end timing of the first calculation period, thereby providing a dedicated counter for grasping the end timing of the first calculation period. The storage capacity in the main RAM 65 for grasping the end timing of the first calculation period is reduced as compared with the configuration provided separately.

The main CPU 63 recognizes that the second calculation period has ended based on the value of the common write pointer 617 making one round to become “0”. Therefore, as compared with the configuration in which a dedicated counter for grasping the end timing of the second calculation period is provided separately from the common write pointer 617, the main side for grasping the end timing of the second calculation period. The storage capacity of the RAM 65 can be reduced.

<91st Embodiment>
The present embodiment is different from the 90th embodiment in that a counter area for storing 10 ball output rate data in each of the latest 10 unit calculation periods is provided. The configuration different from that of the 90th embodiment will be described below. The description of the same configuration as the 90th embodiment is basically omitted.

FIG. 333 is an explanatory diagram for explaining various areas of the work area 223 for non-specific control used for managing the game history in the embodiment.

In the work area 223 for non-specific control, a common management counter area 621 is provided as shown in FIG. 333 instead of the common management buffer 616 in the 90th embodiment. The common management counter area 621 includes a payout rate in the entire unit calculation period for four times (the payout rate in the entire unit calculation period for the last four times and the payout rate in the first calculation period) and the entire unit calculation period for ten times. Information (specifically, 10 pieces in each of the last 10 unit calculation periods) for calculating the payout rate in (the payout rate in the entire unit calculation period for the last 10 times and the payout rate in the second calculation period) Is a counter area in which the payout rate data of is stored. In the common management counter area 621, ten payout rate counters 621a to 621j are provided as counters for storing the payout rate data in the unit calculation period. In the common management counter area 621, specifically, the 0th payout rate counter 621a in which the payout rate in the latest unit calculation period is stored, and the payout rate in the immediately preceding unit calculation period are stored. A first payout rate counter 621b, a second payout rate counter 621c that stores the payout rate in the unit calculation period two years before, and a third that stores the payout ratio in the unit calculation period three years before. A payout rate counter 621d, a fourth payout rate counter 621e that stores a payout rate in a unit calculation period four years ago, and a fifth payout ratio that stores a payout rate in a unit calculation period five years ago. A rate counter 621f, a sixth payout rate counter 621g that stores a payout rate in a unit calculation period six years ago, and a seventh payout ratio counter that stores a payout rate in a unit calculation period seven years ago. 621h, an eighth payout rate counter 621i that stores the payout rate in the unit calculation period that is eight previous, and a ninth payout ratio counter 621j that stores the payout rate in the unit calculation period that is nine previous. Is provided. The 0th to 9th payout rate counters 621a to 621j all have the same storage capacity, and specifically, the payout rate information (numerical information of any one of "0" to "999") is stored. It has a storage capacity of 10 bits so that it can be stored.

Next, the payout rate storage processing executed by the main CPU 63 will be described with reference to the flowchart in FIG. The payout rate storage process is executed in step SL112 of the check process (FIG. 325) when the unit calculation period ends. Further, the processing of steps SL701 to SL720 in the payout rate storage processing is executed by using the non-specific control program and the non-specific control data in the main CPU 63.

In the payout rate storage processing, first, the data shift processing of the common management counter area 621 is executed (step SL701). In the data shift process, the payout rate information stored in the 0th to 9th payout rate counters 621a to 621j in the common management counter area 621 is changed from the 8th payout rate counter 621i to the 9th payout rate counter 621j. , 7th payout rate counter 621h → 8th payout rate counter 621i, 6th payout rate counter 621g → 7th payout rate counter 621h, 5th payout rate counter 621f → 6th payout rate counter 621g, 4 out rate counter 621e→fifth out rate counter 621f, third out rate counter 621d→fourth out rate counter 621e, second out rate counter 621c→third out rate counter 621d, first out The shift is performed in the order of the ball rate counter 621b→the second ball payout rate counter 621c, the 0th ball payout rate counter 621a→the first ball payout rate counter 621b. As a result, the payout rate in the unit calculation period nine times before is stored in the ninth payout ratio counter 621j, and the payout rate in the unit calculation period eight times before is stored in the eighth payout ratio counter 621i. The payout rate in the previous unit calculation period is stored in the seventh payout rate counter 621h, and the payout rate in the unit calculation period six times before is stored in the sixth payout rate counter 621g. The payout rate in the calculation period is stored in the fifth payout rate counter 621f, the payout rate in the unit calculation period four times before is stored in the fourth payout ratio counter 621e, and the payout rate in the unit calculation period three times before is calculated. The payout rate is stored in the third payout rate counter 621d, the payout rate in the unit calculation period two times before is stored in the second payout ratio counter 621c, and the payout rate in the unit calculation period one time before is the first. It is stored in the 1-ball-drawing-rate counter 621b. In the data shift processing of the common management counter area 621, the LDIR instruction is used to shift the information as described above. In the LDIR instruction, the information stored in the storage area is shifted (copied) to the storage area by designating the address of the storage area of the information and the address of the storage area of the information. Becomes Further, in the data shift processing of the common management counter area 621 in step SL701, the 0th payout rate counter 621a is cleared to "0" after the above information shift.

After that, the current payout rate data stored in the current payout rate area 599 is grasped (step SL702), and the grasped current payout rate data is stored in the 0th payout rate counter 621a (step SL703). ). As a result, the 0th payout rate counter 621a is in a state where the payout rate data in the unit calculation period ended this time is stored. In the common management counter area 621, the counter for storing the payout rate data in the latest unit calculation period is fixed to the 0th payout rate counter 621a, so that the payout rate data in the unit calculation period ended this time The processing configuration for specifying the writing destination is simplified.

After that, the addition processing of the write number counter 622 is executed (step SL704). As shown in FIG. 333, in the work area 223 for non-specific control, the main CPU 63 can keep track of the number of times the payout rate data in the unit calculation period is written in the common management counter area 621. Is provided. The write number counter 622 is a loop counter in which 1 is added to the previous value each time it is updated, and after reaching the maximum value (specifically, “19”), it returns to “0”. The writing number counter 622 is updated every time the payout rate data in the unit calculation period is written in the common management counter area 621. In the addition processing of the write number counter 622 in step SL704, the value of the write number counter 622 is incremented by 1, and when the value of the write number counter 622 after adding 1 exceeds the maximum value “19”, the write number counter is counted. The value of 622 is cleared to "0".

Then, it is determined whether the first notification start flag 608 provided in the non-specific control work area 223 is set to "1" (step SL705). The first notification start flag 608 is the same as in the 89th embodiment, and displays the winning rate of various areas 606a to 606d in the first display target area 606 on the first to fifth notification display devices 591 to 595. This is a flag for the main CPU 63 to know whether or not it is in the situation of executing. The first notification start flag 608 has a value of “0” when the supply of operating power to the pachinko machine 10 is started for the first time after the pachinko machine 10 is manufactured. The value of the first notification start flag 608 is also “0” when the non-specific control work area 223 including the first notification start flag 608 is cleared and initialized to “0”. In the case where the first notification start flag 608 is in a situation where four payout rate data in each unit calculation period of four times are stored in the payout rate counters 621a to 621j in the common management counter area 621, " 1” is set. The state in which the value of the first notification start flag 608 is "0" corresponds to the state in which the number of ball output rate data stored in the ball output rate counters 621a to 621j in the common management counter area 621 is three or less. doing. When “1” is not set in the first notification start flag 608, various areas of the first display target area 606 are displayed in the first to fifth notification display devices 591 to 595, as in the 89th embodiment. The payout rate stored in 606a to 606d is not displayed.

When a negative determination is made in step SL705, it is determined whether or not the value of the write number counter 622 updated in step SL704 is "4" (step SL706). When the affirmative determination is made in step SL706, it means that the payout rate data in the unit calculation period stored in the common management counter area 621 is four, so the first notification start flag 608 is set. "1" is set (step SL707).

When a positive determination is made in step SL705 or when the process of step SL707 is performed, the first payout rate calculation process is executed (step SL708). As in the 89th embodiment, in the first payout rate calculation processing, "1" is set in the first notification start flag 608 (a positive determination is made in step SL705, or step SL707). Is executed).

In the first payout rate calculation processing in step SL708, first, the calculation area 598 in the work area 223 for non-specific control is cleared to "0". After that, the payout rate data stored in the 0th payout rate counter 621a is set in the calculation area 598, and the first payout rate counter 621b, the second payout rate counter 621c and the value in the calculation area 598 are set. The three payout rates stored in the third payout rate counter 621d are added. As a result, the total value of the four payout rates in the latest four unit calculation periods is set in the calculation area 598. After that, by dividing the total value by “4”, the payout rate in the entire unit calculation period for the latest four times is calculated, and the calculated payout rate is stored in the calculation area 598. Similar to the 89th embodiment, the payout rate in the entire unit calculation period for the latest four times is calculated as 3-digit numerical information in the range of “0” to “999”. By executing the first payout rate calculation processing in step SL708, the calculation area 598 is in a state in which the payout rate data for the entire last four unit calculation periods is stored.

In the present embodiment, in the common management counter area 621, the counters for storing the four payout rate data in each of the latest four unit calculation periods are fixed to the 0th to 3rd payout rate counters 621a to 621d. Therefore, the processing configuration for specifying the counter in the common management counter area 621 in which the four payout rate data in each of the latest four unit calculation periods are stored is simplified.

After executing the first payout rate calculation processing in step SL708, in steps SL709 to SL712, the same processing as step SL511 to step SL514 of the payout rate storage processing (FIG. 331) in the 90th embodiment is performed. Execute. Specifically, the overwrite process of the first unit update area 606a is executed (step SL709). In the overwrite processing, the first unit update area 606a is overwritten with the ball output rate data in the entire unit calculation period for the latest four times calculated in step SL708.

Then, it is determined whether or not it is the timing when the first calculation period ends (step SL710). In step SL710, when the value of the write count counter 622 is any of "0", "4", "8", "12" and "16", it is determined that it is the timing when the first calculation period ends. .. When an affirmative determination is made in step SL710, the process for updating the latest area 606b of the first calculation period, the first history area 606c of the first calculation period, and the second history area 606d of the first calculation period ( The processing of steps SL711 to SL712) is executed.

Specifically, first, the first data shift process is executed (step SL711). The contents of the first data shift process are as already described in the 89th embodiment. By executing the first data shift process, the payout rate data in the first calculation period that is two times before the first calculation period that has ended this time is stored in the second history area 606d of the first calculation period, and the present end The payout rate data in the first calculation period, which is one time before the first calculation period, is stored in the first history area 606c of the first calculation period, and the nearest area 606b of the first calculation period is cleared to “0”.

After that, the payout rate data stored in the first unit update area 606a is stored in the area 606b closest to the first calculation period (step SL712). As described above, the first unit update area 606a stores the payout rate data for the entire unit calculation period for the latest four times. When one first calculation period ends, the latest four unit calculation periods are the unit calculation periods for four times included in the first calculation period ended this time. For this reason, the final payout rate data in the first calculation period ended this time is stored in the first unit update area 606a, and in step SL712, the area closest to the area 606b closest to the first calculation period is also ended. The final payout rate data for one calculation period is stored.

Then, it is determined whether or not "1" is set in the second notification start flag 609 provided in the work area 223 for non-specific control (step SL713). The second notification start flag 609, similar to the 89th embodiment, displays the payout rate of each area 607a to 607d in the second display target area 607 on the first to fifth notification display devices 591 to 595. This is a flag for the main CPU 63 to know whether or not it is in the situation of executing. The second notification start flag 609 has a value of “0” when the supply of operating power to the pachinko machine 10 is started for the first time after the pachinko machine 10 is manufactured. The value of the second notification start flag 609 is also “0” when the non-specific control work area 223 including the second notification start flag 609 is cleared and initialized to “0”. In the case where the second notification start flag 609 is in a situation in which the payout rate counters 621a to 621j in the common management counter area 621 store ten payout rate data in each unit calculation period for ten times, “ 1” is set. The state in which the value of the second notification start flag 609 is “0” indicates that the payout rate data is displayed in at least one of the payout rate counters 621a to 621j in the common management counter area 621. Corresponds to the state where is not stored. When "1" is not set in the second notification start flag 609, various areas of the second display target area 607 are displayed in the first to fifth notification display devices 591 to 595 as in the 89th embodiment. The payout rate stored in 607a to 607d is not displayed.

When a negative determination is made in step SL713, it is determined whether or not it is the timing when the second calculation period ends (step SL714). In step SL714, when the value of the write count counter 622 after being updated in step SL704 is “0” or “10”, it is determined that it is the timing when the second calculation period ends. When an affirmative determination is made in step SL714, it means that the payout rate data in the unit calculation period stored in the common management counter area 621 has reached 10, so the second notification start flag 609 is set. "1" is set (step SL715).

When a negative determination is made in step SL713 or when the process of step SL715 is executed, the second payout rate calculation process is executed (step SL716). In the second payout rate calculation process, first, the calculation area 598 in the work area 223 for non-specific control is cleared to “0”, and the payout rate data ( Numerical information of "0" to "999") is set in the calculation area 598. After that, by adding the nine payout rates stored in the first to ninth payout rate counters 621b to 621j of the common management counter area 621 to the value of the calculation area 598, ten payouts are obtained. Calculate the sum of the rates. Then, the value in the calculation area 598 is divided by “10” to calculate the payout rate in the entire unit calculation period for the last 10 times, and the calculated payout rate is stored in the calculation area 598. As already described, the payout rate in the entire unit calculation period for the last 10 times is calculated as 3-digit numerical information in the range of “0” to “999”. As a result, the payout rate in the entire unit calculation period for the last 10 times is stored in the calculation area 598.

After that, the overwriting process of the second unit update area 607a is executed (step SL717). In the overwrite processing, the payout rate data in the entire unit calculation period for the last 10 times calculated in step SL716 is overwritten in the second unit update area 607a. Similar to the 89th embodiment, the payout rate data stored in the second unit update area 607a is the payout rate data for the entire last 10 unit calculation periods each time one unit calculation period ends. Will be updated.

Then, it is determined whether or not it is the timing when the second calculation period ends (step SL718). In step SL718, when the value of the write number counter 622 updated in step SL704 is “0”, it is determined that the second calculation period ends. When a negative determination is made in step SL718, the main payout rate storage processing is ended as it is.

On the other hand, if a positive determination is made in step SL718, the process proceeds to step SL719. In Step SL719 to Step SL720, the same processing as Step SL223 to Step SL224 of the payout rate storage processing (FIG. 326) in the 89th embodiment is executed. Specifically, first, the second data shift process is executed (step SL521). The content of the second data shift process is as already described in the 89th embodiment. By executing the second data shift process, the payout rate data in the second calculation period two times before the second calculation period ended this time is stored in the second history area 607d of the second calculation period, and the present end The payout rate data in the second calculation period, which is one time before the second calculation period, is stored in the first history area 607c of the second calculation period, and "0" is cleared in the nearest area 607b of the second calculation period.

After that, the payout rate data stored in the second unit update area 607a is stored in the area 607b closest to the second calculation period (step SL720), and this payout rate calculation processing is ended. As described above, the second unit update area 607a stores the payout rate for the last ten unit calculation periods. When the value of the second write pointer 604 makes one round and one second calculation period ends, the latest 10 unit calculation periods are the 10 unit calculation periods included in the second calculation period ended this time. For this reason, the final payout rate data in the second calculation period ended this time is stored in the second unit update area 607a, and in step SL720, the area close to this time in the nearest area 607b of the second calculation period is also ended. The final payout rate data for the two calculation periods is stored.

According to this embodiment described in detail above, the following excellent effects are exhibited.

Based on the value of the write number counter 622, the end timing of the first calculation period and the end timing of the second calculation period are grasped. In the configuration in which the counter for grasping the end timing of the first calculation period and the counter for grasping the end timing of the second calculation period are separately provided, the end of the first calculation period and the second calculation period A process of updating the two counters is necessary to grasp the timing. On the other hand, in the present embodiment, the first calculation period and the second calculation period are determined based on the value of the single write counter 622, so that the first calculation period and the second calculation period are determined. The storage capacity in the main RAM 65 for grasping the end timing of the second calculation period is reduced, and the processing configuration for grasping the end timing of the first calculation period and the second calculation period is simplified.

In the common management counter area 621, the counters that store the four payout rate data in each of the last four unit calculation periods are fixed to the 0th to third payout rate counters 621a to 621d. In the area 621, the processing configuration for specifying the counter that stores the four payout rate data in each of the latest four unit calculation periods is simplified.

In the common management counter area 621, the counter for storing the payout rate data in the latest unit calculation period is fixed to the 0th payout rate counter 621a, so that the payout rate data in the unit calculation period ended this time The processing configuration for specifying the writing destination is simplified.

<92nd Embodiment>
In this embodiment, the type of payout rate to be displayed is different from that of the 89th embodiment. The structure different from that of the 89th embodiment will be described below. The description of the same configuration as the 89th embodiment is basically omitted.

In the present embodiment, the first display target area 606 in the work area 223 for non-specific control is provided with the closest area 606b of the first calculation period, while the first unit update area in the 89th embodiment described above. 606a, the first history area 606c of the first calculation period, and the second history area 606d of the first calculation period are not provided. Further, the second display target area 607 in the present embodiment is provided with the closest area 607b of the second calculation period, while the second unit update area 607a and the second calculation period of the 89th embodiment described above are provided. The first history area 607c and the second history area 607d of the second calculation period are not provided.

In the present embodiment, the main control device 60 is provided with the first notification display device 591, the third notification display device 593, the fourth notification display device 594, and the fifth notification display device 595, while The second notification display device 592 in the 89th embodiment is not provided. The first, third to fifth notification display devices 591 and 593 to 595 are provided side by side on the element mounting surface of the main control board 61.

The payout rate in the latest first calculation period stored in the latest area 606b in the first calculation period and the payout rate in the latest second calculation period stored in the latest area 607b in the second calculation period are the first In a situation where "1" is set in the notification start flag 608 and the second notification start flag 609, the first, third to fifth notification display devices 591, 593 to 595 are alternately notified. Specifically, each time the display continuation period (specifically, 5 seconds) elapses, notification is made in a predetermined order of the latest area 606b of the first calculation period→the latest area 607b of the second calculation period. The payout rate is changed, and the change of the payout rate to be notified in the predetermined order is repeated.

FIG. 335(a) shows that the payout rate stored in the nearest area 606b in the first calculation period is "1" in the calculation start flag 597 (FIG. 322) in the work area 223 for non-specific control. FIG. 335(b) is an explanatory diagram for explaining the display contents of the first, third to fifth notification display devices 591, 593 to 595 in the case of being notified, and FIG. 335(b) shows “1” in the calculation start flag 597. The display contents of the first, third to fifth notification display devices 591, 593 to 595 when the payout rate stored in the immediate area 607b of the second calculation period is notified in the set situation will be described. FIG. FIG. 335(a) is an example of display contents of the first, third to fifth notification display devices 591, 593 to 595 when the payout rate stored in the nearest area 606b of the first calculation period is notified. FIG. 335(b) shows the display contents of the first, third to fifth notification display devices 591, 593 to 595 when the payout rate stored in the nearest area 607b of the second calculation period is notified. An example is shown.

Similar to the 89th embodiment, in the first notification display device 591, the payouts stored in the first display target area 606 in the first, third to fifth notification display devices 591, 593 to 595. A display indicating that the situation is informing the rate and a display indicating that the situation is informing the payout rate stored in the second display target area 607 are performed. Specifically, when notifying the payout rate of the nearest area 606b during the first calculation period, the character "d" is displayed on the first notification display device 591 as shown in FIG. 335(a). .. Further, when notifying the payout rate of the nearest area 607b in the second calculation period, the character "d." is displayed on the first notification display device 591 as shown in FIG. 335(b). When information other than the payout rate is notified on the first, third to fifth notification display devices 591, 593 to 595, the letters "d" and "d." are displayed on the first notification display device 591. Is never displayed. The manager of the game hall confirms that the character "d" is displayed on the first notification display device 591, and thereby the first, third to fifth notification display devices 591, 593 to 595. It is possible to know that the payout rate in the most recent first calculation period has been notified in, and also to confirm that the character "d." is displayed on the first notification display device 591. Thus, it is possible to know that the first, third to fifth notification display devices 591, 593 to 595 have been notified of the payout rate in the latest second calculation period.

Similar to the 89th embodiment, the third notification display device 593 displays the hundreds digit of the payout rate stored as three-digit numerical information in the range of “0” to “999”. The tenth digit of the payout rate is displayed on the fourth notification display device 594, and the one digit of the payout rate is displayed on the fifth notification display device 595.

According to this embodiment described in detail above, the following excellent effects are exhibited.

By making it possible to ascertain the type of the payout rate displayed on the first, third to fifth display devices 591, 593 to 595 based on the display on the first display device 591. It is possible to set the number of notification display devices to one so that the type of the displayed payout rate can be grasped. Thereby, while suppressing an increase in the number of notification display devices, the three-digit payout rate is displayed on the first, third to fifth notification display devices 591, 593 to 595. You can

The first, third to fifth notification display devices 591, 593 to 595 alternately display the payout rate in the latest first calculation period and display the payout rate in the latest second calculation period. As a result, while suppressing an increase in the number of notification display devices, it is possible to grasp not only the presence or absence of an abnormality in the payout rate in the first calculation period but also the degree of abnormality. It is possible to grasp not only the presence or absence of an abnormality in the payout rate during the calculation period but also the degree of the abnormality.

<Thirty-third embodiment>
In this embodiment, the processing configuration relating to management of the game history and the processing configuration relating to display control of the first to fourth notification display devices 201 to 204 are different from those of the 35th embodiment. The configuration different from that of the 35th embodiment will be described below. The description of the same configuration as the thirty-fifth embodiment is basically omitted.

FIG. 336(a) is an explanatory diagram for explaining various areas of the work area 223 for non-specific control in the present embodiment.

Similar to the eleventh embodiment, the first to fourth notification display devices 201 to 204 (FIG. 53) are provided side by side on the element mounting surface of the main control board 61. As in the 33rd embodiment, when the setting value is confirmed, it indicates that the setting value is being confirmed on the first to fourth notification display devices 201 to 204. In addition to the display and the display showing the current setting value, when the setting value is being updated, the setting value is being updated on the first to fourth notification display devices 201 to 204. A display indicating that there is and a display indicating the current set value are displayed.

As shown in FIG. 336(a), in the calculation result storage area 234 of the work area 223 for non-specific control, as in the 35th embodiment, a current area 311 in which the latest base value is stored, The first history area 312 in which the final base value in the previous calculation period is stored, the second history area 313 in which the final base value in the previous calculation period is stored, and the third history area 313 A third history area 314 for storing the final base value in the calculation period is provided. As already described in the thirty-fifth embodiment, in the first to fourth notification display devices 201 to 204, every time the display continuation period (specifically, 5 seconds) elapses, the current area 311 → the first history The base value to be notified is switched in a predetermined order of area 312→second history area 313→third history area 314, and the switching of the base value to be notified is repeated in the predetermined order. ..

As already described in the thirty-fifth embodiment, the base value is the total number of game balls discharged from the game area PA in a situation that is neither the open/close execution mode due to the big hit result nor the high frequency support mode (that is, the game area). It is the ratio of the total payout number of game balls to the total number of game balls supplied to the PA. As shown in FIG. 336(a), the work area 223 for non-specific control is provided with a normal counter area 231 as in the 35th embodiment. Then, in the normal counter area 231, a normal general prize winning counter 231a, a normal special electric prize counter 231b, a normal first operation counter 231c, a normal second operation counter 231d and a normal out counter. 231e is provided. In a situation where neither the open/close execution mode by the jackpot result nor the high frequency support mode is available, when one game ball enters the general winning opening 31, the value of the normal general winning counter 231a is incremented by 1, When one game ball enters the winning device 32, the value of the special electric prize winning counter 231b for normal is incremented by 1, and when one game ball enters the first working opening 33, it is for normal use. The value of the first operation counter 231c of 1 is added, and when one game ball enters the second operation port 34, the value of the normal second operation counter 231d is increased by 1 and is added to the outlet 24a. When one game ball enters, the value of the normal out counter 231e is incremented by 1.

When the values of the various counters 231a to 231e in the normal counter area 231 are K91 to K95 in a situation where neither the open/close execution mode based on the jackpot result nor the high frequency support mode is used, the base values are as follows.
Base value: total payout number of game balls (K91 x "number of prize balls for winning in general prize hole 31" + K92 x "number of prize balls for winning in special electric prize winning device 32" + K93 x "to first operating port 33" Ratio of the total number of game balls discharged from the game area PA (K91+K92+K93+K94+K95)+K94דnumber of prize balls for winning in the second operation port 34”)/K94.

As shown in FIG. 336( a ), the work area 223 for non-specific control is provided with a total number area 631 and a total payout number area 632. The total number area 631 is the total number of game balls discharged from the game area PA in a situation that is neither the open/close execution mode due to the big hit result nor the high frequency support mode (that is, the total number of game balls supplied to the game area PA). Is a counter that stores the total number data, which is numerical information indicating The main CPU 63 calculates the total number data by summing the values of the various counters 231a to 231e in the normal counter area 231. The total number data is 2-byte numerical value information indicating a numerical value of "0" to "65535".

The total payout amount area 632 is a counter that stores the total payout amount information, which is numerical information indicating the total payout amount of the game balls in a situation that is neither the open/close execution mode based on the jackpot result nor the high frequency support mode. The main CPU 63 calculates the total payout amount information based on the values of the various counters 231a to 231e in the normal counter area 231. The total payout amount area 632 is made up of 3 bytes and can store numerical information having a value obtained by subtracting 1 from the cube of “256” as an upper limit. When the values of the general prize winning counter 231a for normal use, the special electric prize winning counter 231b for normal use, the first operation counter 231c for normal use, and the second operation counter 231d for normal use are K91 to K94, the jackpot is a big hit. The total payout number of gaming balls in a situation that is neither the opening/closing execution mode nor the high frequency support mode depending on the result is calculated by the following formula.
-Total payout number: K91 x "number of prize balls for winning in the general prize opening 31" + K92 x "number of prize balls for winning in the special electric prize winning device 32" + K93 x "number of prize balls for winning in the first working opening 33" “+K94דnumber of prize balls for winning in the second operating port 34”.

In the present embodiment, a residual process (FIG. 347) described later is performed in the main process (FIG. 132). The residual process (FIG. 347) is a loop process that is repeatedly executed at the end of the main process (FIG. 132), and the base value is calculated in the residual process (FIG. 347). The main CPU 63 grasps the total payout amount information stored in the total payout amount area 632 to grasp the total payout amount of the game balls in a situation that is neither the open/close execution mode by the jackpot result nor the high frequency support mode. At the same time, by grasping the total number data stored in the total number area 631, the total number of game balls discharged from the game area PA in a situation where neither the opening/closing execution mode nor the high frequency support mode depending on the jackpot result is grasped. To do. Then, by dividing the grasped total payout amount by the grasped total number of game balls discharged from the game area PA, the base value is calculated as a value up to the fourth decimal place. After that, the base value is rounded to the third decimal place by rounding off the calculated fourth decimal place. After that, the base value is rounded off to the second decimal place by rounding off the third decimal place in the base value up to the third decimal place. After that, the base value up to the second decimal place is overwritten in the current area 311 to overwrite the latest base value stored in the current area 311.

As already described in the thirty-fifth embodiment, the total number of game balls discharged from the game area PA in a situation that is neither the open/close execution mode due to the big hit result nor the high frequency support mode (that is, supplied to the game area PA). When the total number of game balls) reaches the shift reference number of 60,000, one calculation period of the base value ends. Since a maximum of 100 game balls are shot in one minute in the pachinko machine 10, 60000 is the maximum number of shots in 10 hours. Each base value stored in the first to third history areas 312 to 314 is a final base value in the corresponding calculation period, while the latest base value stored in the current area 311 has not ended. This is the base value for the current calculation period. Therefore, the latest base value displayed on the first to fourth notification display devices 201 to 204 is the past base value displayed on the first to fourth notification display devices 201 to 204 (first to fourth The degree of convergence is lower than the base values stored in the three history areas 312 to 314).

The latest base value stored in the current area 311 is the total number of game balls discharged from the game area PA in the situation where neither the open/close execution mode by the big hit result nor the high frequency support mode is calculated in the current calculation period ( That is, the smaller the total number of game balls supplied to the game area PA, the lower the degree of convergence, and the larger the total number of game balls discharged from the game area PA, the higher the degree of convergence.

In the present embodiment, the first to fourth notification display devices 201 to 204 are provided for the purpose of grasping the degree of convergence of the latest base values displayed on the first to fourth notification display devices 201 to 204. The total number information is displayed at. Further, as in the 35th embodiment, the total number of game balls discharged from the game area PA in the situation where neither the open/close execution mode by the big hit result nor the high frequency support mode is 6000 which is the initial calculation number. When the latest base value is displayed on the first to fourth notification display devices 201 to 204 in a situation in which it has not been reached, the calculation initial display is performed. As already described in the thirty-fifth embodiment, in the calculation initial display, the characters (the characters “b” and “L.”) displayed on the first and second notification display devices 201 and 202 are displayed in a blinking manner. As a result, in a situation in which the total number of game balls discharged from the game area PA does not reach the calculation initial number (specifically 6000) in a situation where neither the open/close execution mode by the jackpot result nor the high frequency support mode is used. This is a display that makes it possible to know that there is something.

First, the display of the total number information will be described. In the present embodiment, when the reset button 68c (FIG. 53) is pressed while the most recent base value is being displayed on the first to fourth notification display devices 201 to 204, the first The total number information in which the upper four digits of the total number data are displayed on the fourth notification display devices 201 to 204 is displayed. By making it possible to grasp the total number data in the current calculation period of the base value, it is possible to grasp the degree of convergence of the latest base value displayed on the first to fourth notification display devices 201 to 204. You can

FIG. 336(b) is an explanatory diagram for explaining the display contents of the first to fourth notification display devices 201 to 204 in the situation where the total number information is displayed. As described above, the total number data is 2-byte numerical value information indicating any numerical value of “0” to “65535”. As shown in FIG. 336(b), when the total number information is displayed on the first to fourth notification display devices 201 to 204, the first notification display device 201 is displayed on the first order display device 201 in the thousands position. Is displayed (“1” in FIG. 366(b)), and the thousands digit (“2” in FIG. 366(b)) in the total number data is displayed on the second notification display device 202, The hundreds digit (“3” in FIG. 366(b)) of the total number data is displayed on the third notification display device 203, and the tens digit of the total number data is displayed on the fourth notification display device 204. A number (“0” in FIG. 366(b)) is displayed. This makes it possible to grasp the upper four digits of the total number data (“1230” in FIG. 366(b)) and also the degree of convergence of the latest base value. ..

When the manager of the game hall notices that the latest base value displayed on the first to fourth notification display devices 201 to 204 is out of the theoretical value range of the base value, the reset button 68c is pressed. It is possible to display the upper 4 digits of the total number data (total number information) on the first to fourth notification display devices 201 to 204 by operating. The total number data grasped based on the total number information (upper 4 digits of the total number data) displayed on the first to fourth notification display devices 201 to 204 is the final total in the calculation period of the base value. If it is smaller than the number data (specifically, 60000), it can be understood that the degree of convergence of the latest base value is low. In addition, when the total number data grasped based on the total number information is close to the final total number data (specifically, 60000) in the base value calculation period, convergence of the latest base value is not detected. You can understand that the degree is high. For example, in the display content shown in FIG. 366(b), the total number data is numerical information indicating any of “12300” to “12309”, and is compared with the final state in which the total number data is “60000”. Therefore, it can be understood that the degree of convergence about the latest base value is low.

If the latest base value is out of the theoretical value range of the base value, if the degree of convergence of the latest base value is low, the manager of the gaming hall determines the final base value in the current calculation period. It can be understood that there is a possibility that will fall within the theoretical value range of the base value. Further, if the degree of convergence of the latest base value is high, it can be understood that the final base value in the current calculation period is likely to be out of the theoretical value range of the base value.

As the total number information, since it is configured to display the upper 4 digits of the total number data, which is any numerical information of "0" to "65535", the whole of the total number data (5-digit number) can be displayed. It is possible to grasp the degree of convergence of the latest base value while suppressing an increase in the number of the notification display devices 201 to 204 as compared with the configuration for displaying.

The display of the total number information is executed regardless of whether or not the total number data has reached the calculation initial number (specifically, 6000 pieces). That is, the display of the total number information is executed regardless of whether or not it is a period in which the calculation initial display is performed on the first to fourth notification display devices 201 to 204. Therefore, even after the period in which the total number data reaches the calculation initial number and the calculation initial display is completed, the most recent base value is displayed on the first to fourth notification display devices 201 to 204. By pressing the reset button 68c in a situation where the total number of pieces of information is displayed on the first to fourth notification display devices 201 to 204, the degree of convergence of the latest base value can be grasped. ..

The display duration of the total number information is 5 seconds like the display duration of the base value. In the first to fourth notification display devices 201 to 204, the display of the latest base value is started after the display of the total number information is continued for 5 seconds. With the configuration in which the display of the base value and the display of the total number information are performed by the common first to fourth display devices 201 to 204, the monitoring burden on the manager of the game hall that monitors the base value. Can be reduced.

Next, the configuration of the main RAM 65 for displaying the total number information (the upper four digits of the total number data) will be described. As shown in FIG. 336(a), in the work area 223 for non-specific control of the main RAM 65, a display target setting area 276 is provided as in the 33rd embodiment. As already described in the thirty-fifth embodiment, every time the base value display continuation period (specifically, 5 seconds) elapses, the calculation result of the base value to be displayed according to the predetermined display order is the current area. 311, the first history area 312, the second history area 313, and the third history area 314 are read, and the calculation result data of the read base values are stored in the display target setting area 276. The calculation result data of the base value includes display data for causing the third notification display device 203 to display the number corresponding to the first decimal place of the base value to be notified, and the decimal point second to the base value to be notified. Display data for causing the fourth annunciator display device 204 to perform a display corresponding to the digit of the place. Further, as already described in the 35th embodiment, the display type data is also set in the display target setting area 276. In the display type data, a display indicating that the notification target of the first to fourth notification display devices 201 to 204 is the base value (specifically, the character “b” is displayed) is displayed in the first notification display device 201. And the base value of the notification target corresponds to any one of the current state area 311, the first history area 312, the second history area 313, and the third history area 314 in the calculation result storage area 234. Display data for causing the second notification display device 202 to perform a display indicating whether or not. When the base value of the notification target is the base value of the current area 311 on the second notification display device 202, the character “L.” is displayed, and the base value of the notification target is the base value of the first history area 312. If it is a value, the character “1.” is displayed, and if the base value of the notification target is the base value of the second history area 313, the character “2.” is displayed and the base value of the notification target is displayed. Is the base value of the third history area 314, the character “3.” is displayed.

As described above with reference to FIG. 119 in the thirty-third embodiment, the main control board 61 has the fifth display circuit 265 corresponding to the first to fourth notification display devices 201 to 204 (FIG. 53 ). Is provided, and one display IC 266 is provided so as to be common to all of the first to fifth display circuits 261 to 265. Further, as described above with reference to FIG. 120(a) in the thirty-third embodiment, the display area to be supplied to the fifth display circuit 265 is stored in the work area 221 for specific control. 5 display data buffer 275 is provided. When the game history management result is displayed on the first to fourth notification display devices 201 to 204, the display target setting area 276 is stored in the second timer interrupt process (FIG. 346) described later. The read display data is read, and the read display data is stored in the fifth display data buffer 275 (FIG. 120(a)). The display data stored in the fifth display data buffer 275 is transmitted to the display IC 266 (FIG. 119), and the display data is provided from the display IC 266 to the fifth display circuit 265 (FIG. 119). The display based on the display data is displayed on the 4 notification display devices 201 to 204 (FIG. 53 ).

In the present embodiment, when the reset button 68c is pressed while the most recent base value is displayed on the first to fourth notification display devices 201 to 204, the display data corresponding to the most recent base value is displayed. Instead of the display type data, the display data of the total number information corresponding to the total number data stored in the total number area 631 is set in the display target setting area 276. The display data of the total number information corresponds to the display data for causing the first notification display device 201 to perform the display corresponding to the tens digit of the total number data and the thousands digit of the total number data. Display data for causing the second notification display device 202 to perform display, display data for causing the third notification display device 203 to perform display corresponding to the hundreds digit in the total number data, and total number Display data for causing the fourth annunciator display device 204 to perform a display corresponding to the tens digit in the data.

In the second timer interrupt process (FIG. 346) described later, the display data of the total number information stored in the display target setting area 276 is read, and the display data of the read total number information is the fifth display data. It is stored in the buffer 275 (FIG. 120(a)). The display data of the total number information stored in the fifth display data buffer 275 is transmitted to the display IC 266 (FIG. 119), and the display data of the total number information is provided from the display IC 266 to the fifth display circuit 265 (FIG. 119). By doing so, the display based on the display data of the total number information is displayed on the first to fourth notification display devices 201 to 204 (FIG. 53 ).

Next, the manner in which the total number information is displayed on the first to fourth notification display devices 201 to 204 will be described with reference to the time chart of FIG. 337. FIG. 337(a) shows a period in which the total number information is displayed on the first to fourth notification display devices 201 to 204, and FIG. 337(b) shows the first to fourth notification display devices 201 to 204. Shows the period in which the base value is displayed in the current area 311. In FIG. 337(c), the base value is displayed in the third history area 314 on the first to fourth notification display devices 201 to 204. 337 (d) shows a period in which the base value is displayed in the first history area 312 on the first to fourth notification display devices 201 to 204, and FIG. 337 (e) shows the reset button 68c. The operation timing of is shown.

At the timing of t1, when the display of the base value in the third history area 314, which was being performed on the first to fourth notification display devices 201 to 204 as shown in FIG. The display of the latest base value stored in the current area 311 is started on the fourth notification display devices 201 to 204 as shown in FIG. 337(b).

After that, when the reset button 68c is pressed as shown in FIG. 337(e) at the timing of t2 when the most recent base value is displayed, the timing shown in FIG. 337(b) at the timing of t2. As described above, the display of the latest base value, which has been performed on the first to fourth notification display devices 201 to 204, ends halfway, and at the first to fourth notification display devices 201 to 204, the display shown in FIG. As shown in (a), the display of the total number information is started. As described above, in the display of the total number information, the upper four digits of the total number data are displayed on the first to fourth notification display devices 201 to 204.

As shown in FIG. 337(a), the display of the total number information is performed from the timing t2 to the timing t3 for the display continuation period (specifically, 5 seconds). In the first to fourth notification display devices 201 to 204, the display of the latest base value stored in the current area 311 is displayed at the timing t3 when the display of the total number information is finished, as shown in FIG. 337(b). Is started. As shown in FIG. 337(b), the latest base value is displayed during the period (from the timing t1 to the timing t2) during which the latest base value was displayed before the display of the total number information was started. Regardless of the length of the (period), the base value display continuation period (specifically, 5 seconds) is performed from the timing t3 to the timing t4. In the first to fourth display devices 201 to 204, the display of the base value in the first history area 312 is started as shown in FIG. 337(d) at the timing of t4 when the display of the latest base value is finished. It

As described above, when the reset button 68c is pressed in the situation where the most recent base value is displayed on the first to fourth notification display devices 201 to 204, the first to fourth notification messages are displayed. The total number information is displayed on the display devices 201 to 204. The manager of the game hall presses the reset button 68c when discovering that the latest base value displayed on the first to fourth notification display devices 201 to 204 is out of the theoretical value range of the base value. It is possible to grasp the degree of convergence of the latest base value by displaying the upper 4 digits of the total number data by operating.

After the display of the total number information is finished, the most recent base value is displayed on the first to fourth notification display devices 201 to 204. Accordingly, after grasping the degree of convergence of the latest base value based on the display of the total number information, the latest base value can be confirmed again. The display of the most recent base value that starts after the display of the total piece information is continued regardless of the period when the most recent base value was displayed before the display of the total piece information started. It is performed over a period (specifically, 5 seconds). If the configuration is such that the display duration measurement for the most recent base value is restarted after the display of the total number information is completed, it is possible that the most recent base value is displayed before the total number information is displayed. Accordingly, the display continuation period of the latest base value after the display of the total number information is changed. In this configuration, when the reset button 68c is pressed just before the display of the most recent base value is started to start the display of the total number information, the display of the most recent base value after the end of the display of the total number information is performed. The display duration becomes extremely short. On the other hand, in this embodiment, after the display of the total number information is finished, the measurement of the display continuation period for the latest base value is newly started. Therefore, even if the pressing of the reset button 68c is started immediately before the display of the most recent base value is started and the display of the total number information is started, the latest displayed after the display of the total number information is ended. It can be prevented that the display period of the base value of is extremely short.

As described above, the calculation initial display is also performed in this embodiment. As in the 33rd embodiment, the work area 223 for non-specific control is provided with a calculation initial flag. The calculation initial flag is the total number of game balls discharged from the game area PA (that is, the game area) in a situation where the base value calculation period is newly started and the open/close execution mode by the big hit result is neither the high frequency support mode. This is a flag for the main CPU 63 to specify whether or not the total number of game balls supplied to the PA has reached the initial reference number (specifically, 6000). The state in which the operation initial flag is set to "1" corresponds to the state in which the total number of game balls discharged from the game area PA does not reach the initial reference number. When "1" is set in the calculation initial flag, the calculation initial display is performed in the display of the most recent base value on the first to fourth notification display devices 201 to 204.

As already described with reference to FIG. 127(a) in the thirty-fifth embodiment, when the most recent base value is displayed on the first to fourth notification display devices 201 to 204, the first notification The character “b” is displayed on the display device 201, the character “L.” is displayed on the second notification display device 202, and the first decimal point of the base value is displayed on the third notification display device 203. A numeral is displayed, and the numeral for the second decimal place of the base value is displayed on the fourth notification display device 204. In the calculation initial display, blinking display of characters (characters “b” and “L.”) to be displayed on the first notification display device 201 and the second notification display device 202 is performed. Immediately after the start of the calculation period, since there is little information on the game history for calculating the base value, the actual measurement value of the base value may be a value that is largely outside the theoretical value range of the base value. On the other hand, by causing the calculation initial display to be performed immediately after the calculation period is started in this manner, it becomes possible to let the manager of the gaming hall recognize that it is immediately after the calculation period is started. .. When the operation initial display is being performed, the manager of the game hall does not have to operate the reset button 68c, and the latest base displayed on the first to fourth notification display devices 201 to 204 is displayed. It can be understood that the degree of convergence about the value is low.

Next, the internal configuration of the main CPU 63 will be described. As already described in the fifteenth embodiment, the registers of the main CPU 63 include a flag register, various general-purpose registers, auxiliary registers, and index registers. The flag register includes a carry flag, a zero flag, a P/V flag, a sine flag, a half carry flag, etc., and the information in the flag register changes depending on the execution result of an arithmetic instruction, a rotate instruction, an input/output instruction, and the like. The information amount of the flag register is 1 byte.

The main CPU 63 in this embodiment includes a program counter, an instruction register, and an instruction decoder. The main CPU 63 stores the instruction set in the address indicated by the program counter in the instruction register, and advances the program counter to the next instruction to be executed. The instruction decoder decodes the instruction stored in the instruction register and controls each unit of the main CPU 63 according to the decoding result. As a result, various commands are executed in the main CPU 63.

In the present embodiment, as the processing corresponding to the non-specific control, the test shot test execution processing (FIG. 339) executed in step SL807 of the first timer interrupt processing (FIG. 338) described later and the first timer interrupt processing ( There is a management execution process (FIG. 340) executed in step SL821 of FIG. 338) and a total division execution process (FIG. 348) executed in step SM806 of a residual process (FIG. 347) described later. The main CPU 63 executes the processing corresponding to these three non-specific controls by the CALLI command. The contents of the trial shooting test execution process (FIG. 339), the management execution process (FIG. 340), and the total division execution process (FIG. 348) will be described later.

When the process corresponding to the non-specific control is executed by the CALLI instruction, the information in the flag register of the main CPU 63 is saved in the stack area 222 for specific control, and the first timer interrupt process (FIG. 338) and The interrupt of the second timer interrupt process (FIG. 346) described later is prohibited. Then, it corresponds to the process (testing shot test execution process (FIG. 339), management execution process (FIG. 340), or total division execution process (FIG. 348) corresponding to the non-specific control set in the non-specific control program. The subroutine program is executed.

The information in the flag register is saved before the program of the process (testing test execution process (FIG. 339), management execution process (FIG. 340), or total division execution process (FIG. 348)) corresponding to the non-specific control is started. As a result, the information of the flag register in the state before the change after the start of the process corresponding to the non-specific control or the process corresponding to the non-specific control is saved in the stack area 222 for the specific control. Is possible. Further, by prohibiting the interrupt of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) before the program of the process corresponding to the non-specific control is started, the non-specific control is dealt with. It is possible to prevent the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346), which are processes corresponding to the specific control, from being interrupted and activated during execution of the process.

By configuring to execute the process corresponding to the non-specific control by the CALLI instruction, the information of the flag register of the main CPU 63 is specified before the execution of the process corresponding to the non-specific control by one instruction (“CALLI”). Saving to the control stack area 222, prohibiting the interrupts of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346), and starting the program of the process corresponding to the non-specific control. You can Therefore, the instruction for saving the information in the flag register of the main CPU 63 to the stack area 222 for specific control and the interruption of the first timer interrupt processing (FIG. 338) and the second timer interrupt processing (FIG. 346) are prohibited. In order to execute the process corresponding to the non-specific control, the first timer interrupt process (in comparison with the case of separately providing the command for performing the process and the command for starting the program of the process corresponding to the non-specific control) The number of instructions set in the program corresponding to FIG. 338) and the program corresponding to the residual processing (FIG. 347) can be reduced. Thereby, the storage capacity in the main ROM 64 for storing the program corresponding to the first timer interrupt process (FIG. 338) and the program corresponding to the residual process (FIG. 347) can be reduced.

In the present embodiment, the main CPU 63 terminates the process (test firing test execution process (FIG. 339), management execution process (FIG. 340), or total division execution process (FIG. 348)) corresponding to the non-specific control, and performs the specific control. When returning to the process corresponding to, the RETI instruction is executed. By executing the RETI instruction, the information of the flag register saved in the stack area 222 for specific control before the execution of the process corresponding to the non-specific control is returned to the flag register of the main CPU 63, and The state in which the generation of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) are prohibited is switched to the permitted state. As a result, the information in the flag register of the main CPU 63 is restored to the information for executing the specific control, and the first timer interrupt process and the second timer interrupt process can be newly executed.

When the process corresponding to the non-specific control is completed and the process corresponding to the specific control is returned to, the RETI command is executed, so that one command (“RETI”) corresponds to the non-specific control. The information of the flag register saved in the stack area 222 for specific control before execution of the process is restored to the flag register of the main CPU 63, and the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) It is possible to switch from the state in which the occurrence of is prohibited to the state in which it is permitted. Therefore, an instruction for restoring the flag register information saved in the stack area 222 for specific control to the flag register of the main CPU 63 before the execution of the process corresponding to the non-specific control, and the first timer interrupt process ( 338) and the instruction for switching the generation of the second timer interrupt processing (FIG. 346) from the prohibited state to the permitted state are separately provided, as compared with the case of the program of the processing corresponding to the non-specific control. The number of instructions set to can be reduced. As a result, the storage capacity of the main ROM 64 for storing the processing program corresponding to the non-specific control can be reduced.

Next, prior to the description of the first timer interrupt processing (FIG. 338) executed by the main CPU 63, the test shot test information area 633 (FIG. 336(a)) provided in the work area 223 for non-specific control will be described. explain.

The trial shooting test information area 633 is an area in which trial shooting test information to be output to a trial shooting test apparatus (not shown) that is an external device in the trial shooting test is stored. The test shooting test is performed before the pachinko machine 10 is installed in the game hall. In the situation where the test shooting test is performed, the test shooting test information is output from the output side of the MPU 62 of the main control device 60 to the test shooting test device which is an external device via a relay board (not shown). The test shooting test information is information indicating the number of game balls discharged from the game area PA of the pachinko machine 10 in all game states, information indicating the number of game balls to be paid out in all game states, and that a low-probability jackpot result has occurred. The information includes information indicating that a low-win high-precision jackpot result has occurred, and information indicating that the most advantageous jackpot result has occurred. Here, the entire gaming state is a gaming state that is neither the open/close execution mode nor the high frequency support mode, the gaming state that is the open/close execution mode, and the gaming state that is the high frequency support mode.

Next, the first timer interrupt process (FIG. 338) executed by the main CPU 63 will be described. Similar to the thirty-third embodiment, as the timer interrupt processing, the first timer interrupt processing (FIG. 338) which is regularly activated at the 4 millisecond cycle which is the first interrupt cycle, and the second interrupt cycle which is 2 There is a second timer interrupt process (FIG. 346) that is periodically activated in the millisecond cycle. Both the first timer interrupt process and the second timer interrupt process are activated by interrupting the main process (FIG. 132). Further, the second timer interrupt process is activated by interrupting the first timer interrupt process. On the other hand, the first timer interrupt process does not start by interrupting the second timer interrupt process. In addition, in a situation in which both the first timer interrupt process and the second timer interrupt process are not executed, the first interrupt period (specifically 4 ms) and the second interrupt period (specifically 2 ms) When both have passed, the second timer interrupt processing is started first regardless of the order of the cycles. In this respect, it can be said that the second timer interrupt process is a process activated prior to the first timer interrupt process.

FIG. 338 is a flowchart showing the first timer interrupt processing executed by the main CPU 63. The program corresponding to the first timer interrupt process is set to the program for specific control. The processes of steps SL801 to SL821 in the first timer interrupt process are executed in the main CPU 63 using the specific control program and the specific control data. In this embodiment, the activation of the first interrupt process and the second interrupt process (FIG. 346) is not prohibited when the first timer interrupt process is activated. Therefore, it is possible for the second timer interrupt process to interrupt and start the first timer interrupt process. In the second timer interrupt process (FIG. 346) described later, the process for providing the display data to the first to fifth display circuits 261 to 265 is executed as in the 35th embodiment. As already described in the thirty-third embodiment, the first to fifth display circuits 261 to 265 can store and hold the provided display data for a predetermined period (for example, 16 milliseconds). The display data gradually approaches the state of all "0" when the period elapses. In the configuration, by delaying the activation of the second timer interrupt process, the special figure display unit 37a, the special figure reservation display unit 37b, the general figure display unit 38a, the general figure reservation display unit 38b, and the first It is prevented that the display on the fourth notification display devices 201 to 204 flickers.

Various processes of step SL801 to step SL805 and step SL808 to step SL820 in the first timer interrupt process (FIG. 338) are executed by the CALLS instruction. Due to the configuration in which these processes are executed by the CALLS instruction, the program for executing the first timer interrupt process (FIG. 338) is compared with the configuration in which these processes are executed by the CALL instruction (call command). The data capacity can be reduced. Note that the various processes of step SL801 to step SL805 and step SL808 to step SL820 in the first timer interrupt process may be executed by a CALL instruction (call instruction).

In step SL801, a power failure information storage process is executed by the CALLS instruction to perform power failure monitoring (step SL801). In the power outage information storage process, specifically, similarly to the power outage information storage process (FIG. 101) in the thirtieth embodiment, whether or not the power outage signal corresponding to the occurrence of the power shutdown is received from the power outage monitoring board 67. If the occurrence of a power failure is identified by monitoring that, an infinite loop is performed after the power failure processing is executed. In the power failure process, "1" is set to the power failure flag provided in the specific control work area 221, a checksum is calculated, and the calculated checksum is stored in the specific control work area 221.

After the power failure information storage process is performed in step SL801, the random number for lottery update process is executed by the CALLS command (step SL802). In the lottery random number updating process, as in the lottery random number updating process (step S302) of the timer interrupt process (FIG. 11) in the first embodiment, the winning random number counter C1, the jackpot type counter C2, the reach random number counter C3, and Each numerical value information of the general electric opener counter C4 is updated.

After that, the random number initial value updating process is executed by the CALLS instruction (step SL803). In the random number initial value updating process, the numerical value information of the random number initial value counter CINI is updated in the same manner as the random number initial value updating process (step S303) of the timer interrupt process (FIG. 11) in the first embodiment. After that, the fluctuation counter updating process is executed by the CALLS instruction (step SL804). In the fluctuation counter updating process, like the fluctuation counter updating process (step S304) of the timer interrupt process (FIG. 11) in the first embodiment, the numerical information of the fluctuation type counter CS is updated.

After that, the fraud detection process is executed by the CALLS command (step SL805). In the fraud detection process, as in the fraud detection process (step S305) of the timer interrupt process (FIG. 11) in the first embodiment, it is determined whether or not an event set as a fraud monitoring target has occurred. Monitor. In the fraud detection process, the occurrence of multiple types of events is monitored, and by confirming that any of these multiple types of events has occurred, the game stop provided in the work area 221 for specific control is stopped. Set "1" to the flag. As for the game stop flag, in the first timer interrupt process (FIG. 338), a positive determination is made in step SL806 and the processes of steps SL807 to SL821 are not executed, that is, the execution of the process for advancing the game should be stopped. This is a flag for the main CPU 63 to specify whether or not the situation. When the game stop flag is set to "1", the processing in steps SL807 to SL821 is not executed.

After performing the fraud detection process in step SL805, it is determined whether or not "1" is set in either the game stop flag or the in-progress process flag provided in the work area 221 for specific control ( Step SL806). As already described in the 35th embodiment, the start-up processing flag is set to "1" in step S8803 of the main processing (FIG. 132) and is cleared to "0" in step S8820. Is. When an affirmative determination is made in step SL806, the present first timer interrupt processing ends without executing the processing of steps SL807 to SL821.

On the other hand, when a negative determination is made in step SL806, the CALLI command executes the test shot test execution process (FIG. 339) described later (step SL807). As described above, the trial shooting test execution process (FIG. 339) is a process corresponding to the non-specific control.

When the trial shooting test execution process (FIG. 339) is executed by the CALLI instruction, the information in the flag register of the main CPU 63 is first saved in the stack area 222 for specific control. As described above, the flag register includes a carry flag, a zero flag, a P/V flag, a sine flag, a half carry flag, etc., and the information in the flag register changes depending on the execution result of an arithmetic instruction, a rotate instruction, an input/output instruction, or the like. It will be. By saving the information of the flag register before the program of the trial shot test execution process (FIG. 339) is started, the call of the trial shot test execution process (FIG. 339) and the test shot test execution process (FIG. 339) are performed. It is possible to save the information of the flag register in the state before the change after the start of the above in the stack area 222 for specific control.

When the test shot test execution process (FIG. 339) is executed by the CALLI instruction, after the information of the flag register is saved in the stack area 222 for specific control, the first timer interrupt process (FIG. 338) and the later-described 2 The timer interrupt processing (FIG. 346) interrupt is prohibited. This allows the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 338), which are the processes corresponding to the specific control, to be performed during the execution of the test shot test execution process (FIG. 339), which is the process corresponding to the non-specific control. It is possible to prevent 346) from being interrupted and activated.

When the shooting test execution process (FIG. 339) is executed by the CALLI instruction, the information of the flag register is saved in the stack area 222 for specific control, and the first timer interrupt process (FIG. 338) and the second timer interrupt process are performed. After the interruption of (FIG. 346) is prohibited, the program corresponding to the trial shooting test execution process (FIG. 339) described later is started.

In this way, the configuration in which the test firing test execution processing (FIG. 339) is executed by the CALLI instruction allows the information in the flag register of the main CPU 63 to be stored in the stack area 222 for specific control by one instruction (“CALLI”). And the interrupts of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) are prohibited. Then, the program corresponding to the trial shooting test execution process (FIG. 339) can be started. Therefore, the instruction for saving the information in the flag register of the main CPU 63 to the stack area 222 for specific control and the interruption of the first timer interrupt processing (FIG. 338) and the second timer interrupt processing (FIG. 346) are prohibited. The first timer interrupt for executing the test shot test execution process (FIG. 339) is compared with the case where the command for starting the test shot test process and the command for starting the program of the test shot test execution process (FIG. 339) are provided separately. The number of instructions set in the program corresponding to the process (FIG. 338) can be reduced. As a result, the storage capacity in the main ROM 64 for storing the program corresponding to the first timer interrupt processing (FIG. 338) can be reduced.

FIG. 339 is a flowchart showing the test shot test execution processing executed by the main CPU 63. The processes of steps SL901 to SL916 in the trial shooting test execution process are executed by the main CPU 63 using the non-specific control program and the non-specific control data.

In steps SL901 to SL907, the same processes as steps S3901 to S3907 of the management execution process (FIG. 71) in the fifteenth embodiment are executed. Specifically, first, as "LD SP, Y(u+2)", a stack instruction for the non-specific control is set in the stack pointer of the main CPU 63 by the load instruction as a fixed address at the start of the non-specific control (FIG. 68). In step SL901, Y(u+2), which is the information of the last address in (), is set. As already described in the fifteenth embodiment, the stack pointer is the address information for the main CPU 63 to specify the storage area to which information is to be written by the push instruction in the stack areas 222 and 224 (FIG. 68). Is the area to be set. Each time a push instruction is performed, the stack pointer information is updated to the address information of the storage area to be written in the next order, and each time a pop instruction is issued, the stack pointer information is written in the previous order. The information of the address of the storage area is updated. When the stack area 224 for non-specific control is used, the information to be stored is stored from the storage area of the last address in the stack area 224 for non-specific control, and every time the information to be stored is added. Further, the storage area of the storage destination is changed toward the first address side in the stack area 224 for non-specific control. Therefore, in step SL901, the information of the last address in the stack area 224 for non-specific control is set in the stack pointer.

After that, as "LD (_WABUF), WA", the information of the WA register of the main CPU 63 is saved to the WA buffer set in the work area 223 for non-specific control by a load instruction (step SL902). Further, as "LD (_BCBUF), BC", the load instruction saves the information in the BC register of the main CPU 63 to the BC buffer set in the work area 223 for non-specific control (step SL903). Further, as "LD (_DEBUF), DE", the load instruction saves the information in the DE register of the main CPU 63 to the DE buffer set in the work area 223 for non-specific control (step SL904). Further, as "LD (_HLBUF), HL", the information of the HL register of the main CPU 63 is saved in the HL buffer set in the work area 223 for non-specific control by a load instruction (step SL905). Further, as “LD (_IXBUF), IX”, the load instruction saves the information in the IX register of the main CPU 63 to the IX buffer set in the work area 223 for non-specific control (step SL906). Further, as "LD (_IYBUF), IY", the load instruction saves the information in the IY register of the main CPU 63 to the IY buffer set in the work area 223 for non-specific control (step SL907).

As described above, the registers of the main CPU 63 include a flag register, various general-purpose registers, auxiliary registers, and index registers. In this case, in step SL902 to step SL907, each information of the WA register, BC register, DE register, HL register, IX register, and IY register, which is a part of these various general-purpose registers, auxiliary registers, and index registers. Are saved in the corresponding buffer in the work area 223 for non-specific control. The WA register, the BC register, the DE register, the HL register, the IX register, and the IY register each have an information amount of 2 bytes.

The WA register, BC register, DE register, HL register, IX register, and IY register are registers used in the test shooting test process (step SL908) which is a process corresponding to non-specific control. By saving the information set in such registers in the work area 223 for non-specific control prior to the execution of the test shooting test process (step SL908), the information of these registers used in the specific control is tested. It becomes possible to save before the processing (step SL908) is started. Therefore, even if these registers are overwritten during execution of the trial shooting test process (step SL908), when the trial shooting test process (step SL908) ends, the information saved in the work area 223 for non-specific control is saved in these registers. It is possible to return the state of these registers to the state corresponding to the specific control before the test firing test process (step SL908) is performed by returning the state to the register.

Further, instead of saving all the information of various general-purpose registers, auxiliary registers, and index registers to the work area 223 for non-specific control, a test shooting test process (step SL908) corresponding to the non-specific control is performed. In the work area 223 for non-specific control, the information of the WA register, BC register, DE register, HL register, IX register, and IY register to be used is selectively saved in the work area 223 for non-specific control. It is possible to reduce the capacity secured for saving the register information. Therefore, it is possible to save the information in the register as described above while securing a large capacity of the work area 223 for non-specific control that can be used in the trial shooting test process (step SL908). Of course, various general-purpose registers, auxiliary registers, and index registers in the main CPU 63 other than the WA register, BC register, DE register, HL register, IX register, and IY register are compatible with non-specific control. The information set before the processing to be performed is stored and held until the processing corresponding to the non-specific control ends and the processing corresponding to the specific control is restarted.

Further, the register information is not saved in the non-specific control stack area 224 but is saved in the non-specific control work area 223, so that the capacity of the non-specific control stack area 224 can be reduced to that extent. It will be possible. Further, when the stack area 224 for non-specific control is used, the writing order of information is read first from the later information as described above. Therefore, the reading order of information is displaced due to some noise or the like. If this happens, all subsequent read order information will be restored to a different register. The probability of occurrence of such an event increases as the amount of information saved in the stack area 224 for non-specific control increases. On the other hand, by saving the information in the register in the work area 223 for non-specific control, it is possible to prevent the above event from occurring even when there is a large amount of information to be saved. ..

After performing the processes of steps SL902 to SL907, the trial shooting test process is performed (step SL908). When executing the test shooting test process, the program of the subroutine corresponding to the test shooting test process set in the non-specific control program is executed, but when executing the program of the subroutine, the test shooting test process is executed. Information for specifying the return address of the trial shooting test execution process (FIG. 339) later is written in the stack area 224 for non-specific control by the push command. Then, when the trial shooting test process is completed, the information for specifying the return address is read by the pop command, and the program returns to the program of the trial shooting test execution process (FIG. 339) indicated by the return address.

The test shooting test process (step SL908) is executed in the main CPU 63 using the non-specific control program and the non-specific control data. In the trial shooting test process (step SL908), trial shooting test information is generated, and the generated trial shooting test information is stored in the trial shooting test information area 633 in the work area 223 for non-specific control. As described above, the test shooting test information is information indicating the number of game balls discharged from the game area PA of the pachinko machine 10 in all game states, information indicating the number of game balls to be paid out in all game states, and a low-probability jackpot result. Includes information indicating that a low winning award high probability jackpot result has occurred, and information indicating that the most advantageous jackpot result has occurred. As described above, the full game state is a game state that is neither the open/close execution mode nor the high frequency support mode, the game state that is the open/close execution mode, and the game state that is the high frequency support mode. The trial shooting test information stored in the trial shooting test information area 633 is output to the trial shooting test apparatus by the port output processing (step SL808) of the first timer interrupt processing (FIG. 338).

After the trial shooting test process is executed in step SL908, Y(r+β) is set as the fixed address at the time of returning to the specific control to the stack pointer of the main CPU 63 by the load instruction as “LD SP, Y(r+β)”. It is set (step SL909). The Y(r+β) address is set as the address between Y(r+8) and Y(s) in the stack area 222 (FIG. 68) for specific control.

The amount of information stored in the stack area 222 for specific control is always constant immediately before the subroutine of the test shot test execution processing is executed in step SL807 of the first timer interrupt processing (FIG. 338). The information of the stack pointer of the main CPU 63 at the timing (that is, the value of the stack pointer) is constant. In this case, the information stored in the stack area 222 for specific control includes, for example, information on the return address of the first timer interrupt process (FIG. 338) after the test firing test execution process (FIG. 339) is completed. .. The constant information of the stack pointer is Y(r+β). Therefore, when the trial shooting test execution process (FIG. 339) corresponding to the non-specific control ends and the process returns to the process corresponding to the specific control, Y(r+β), which is the certain information, is transferred to the main CPU 63. It is possible to restore the information of the stack pointer to the information immediately before the process corresponding to the non-specific control is started by setting the stack pointer of the above. By setting the fixed information in the stack pointer in this way to restore the information of the stack pointer to the information immediately before the process corresponding to the non-specific control is started, the process corresponding to the non-specific control is performed. It is not necessary to save the information of the stack pointer of the main CPU 63 corresponding to the specific control in the main RAM 65 before starting. Therefore, it is possible to reduce the processing load, and it is not necessary to secure an area for saving in the main RAM 65.

Then, in steps SL910 to SL915, the same processing as steps S3910 to S3915 of the management execution processing (FIG. 71) in the fifteenth embodiment is executed. Specifically, as "LD WA, (_WABUF)", the information saved in the WA buffer of the work area 223 for non-specific control is overwritten in the WA register of the main CPU 63 by the load instruction (step SL910). Further, as "LD BC, (_BCBUF)", the information saved in the BC buffer of the work area 223 for non-specific control is overwritten in the BC register of the main CPU 63 by the load instruction (step SL911). Further, as "LD DE, (_DEBUF)", the information saved in the DE buffer of the work area 223 for non-specific control is overwritten in the DE register of the main CPU 63 by the load instruction (step SL912). Further, as "LD HL,(_HLBUF)", the load instruction overwrites the information saved in the HL buffer of the work area 223 for non-specific control in the HL register of the main CPU 63 (step SL913). Further, as "LD IX, (_IXBUF)", the load instruction overwrites the information saved in the IX buffer of the non-specific control work area 223 in the IX register of the main CPU 63 (step SL914). Further, as "LDIY, (_IYBUF)", the information saved in the IY buffer of the work area 223 for non-specific control is overwritten in the IY register of the main CPU 63 by the load instruction (step SL915). By executing the processing of step SL910 to step SL915, processing corresponding to non-specific control is started for each information of the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63. It is possible to restore the information corresponding to the specific control immediately before.

As described above, as the processing corresponding to the non-specific control, the trial shooting test execution processing (step SL807 in the first timer interrupt processing (FIG. 338)) and the management execution processing (first timer interrupt processing (FIG. 338)) described later are performed. Step SL821) and a total division execution process (step SM806 in the residual process (FIG. 347) described later) described later are present. The information stored in the flag register and various registers of the main CPU 63 when the processing corresponding to the non-specific control is executed is not saved in the main RAM 65 when the processing corresponding to the specific control is restarted. As a result, there is no need to secure a storage area for saving the above information in the specific control work area 221 and the specific control stack area 222.

In addition, the information stored in the flag register and various registers of the main CPU 63 when the process corresponding to the non-specific control (testing test execution process, management execution process and total division execution process) is executed corresponds to the specific control. This information is not used when the process corresponding to the non-specific control is restarted after returning to the process. That is, the information necessary for a plurality of processing times of the processing corresponding to the non-specific control executed with the processing corresponding to the specific control interposed therebetween is the work area 223 for the non-specific control or the stack area for the non-specific control. 224, and is not stored in the flag register and various registers of the main CPU 63. Therefore, even if the information stored in the flag register and various registers of the main CPU 63 is not saved in the main RAM 65 when the process corresponding to the non-specific control is executed, the process corresponding to the non-specific control is not performed. Does not cause any problems.

After performing the process of step SL915, the RETI command is executed as "RETI" (step SL916), and the present test firing test execution process is ended. As described above, by executing the RETI instruction, the information of the flag register saved in the stack area 222 for specific control before the execution of the test shot test execution process (FIG. 339) is returned to the flag register of the main CPU 63. At the same time, the state in which the generation of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) is prohibited is switched to the permitted state. As a result, the information in the flag register of the main CPU 63 is restored to the information for executing the specific control, and the first timer interrupt process and the second timer interrupt process can be newly executed.

With the configuration for executing the RETI instruction, the information of the flag register saved in the stack area 222 for specific control before the execution of the test shot test execution processing by the one instruction (“RETI”) is used as the flag of the main CPU 63. The register can be restored, and the state in which the generation of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) is prohibited can be switched to the permitted state. Therefore, an instruction to restore the information of the flag register saved in the stack area 222 for specific control to the flag register of the main CPU 63 before the execution of the test shot test execution process, and the first timer interrupt process (FIG. 338). And a command for switching from the state in which the generation of the second timer interrupt process (FIG. 346) is prohibited to the state in which the generation is permitted are set in the program corresponding to the test firing test execution process, as compared with the case where the instruction is provided separately. The number of instructions can be reduced. As a result, the storage capacity of the main ROM 64 for storing the program corresponding to the test shot test execution process can be reduced.

As described above, the execution of the RETI instruction permits the generation of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346). Therefore, if the RETI instruction is executed in the situation where the processing corresponding to the non-specific control remains, the first timer interrupt which is the processing corresponding to the specific control in the situation where the processing corresponding to the non-specific control is executed. The process (FIG. 338) or the second timer interrupt process (FIG. 346) is interrupted and activated. On the other hand, since the RETI instruction is executed in step SL916, which is the last step of the trial shooting test execution process (FIG. 339) that is the process corresponding to the non-specific control, the process corresponding to the non-specific control is performed. The CPU 63 of the main side prevents the first timer interrupt process (FIG. 338) or the second timer interrupt process (FIG. 346), which is a process corresponding to the specific control, from being interrupted and activated in the situation where is executed. In the state where the information of the flag register of 1 has been returned to the information for executing the specific control, it is possible to return to the first timer interrupt processing (FIG. 338) which is the processing corresponding to the specific control.

Returning to the explanation of the first timer interrupt processing (FIG. 338), after performing the test shot test execution processing (FIG. 339) in step SL807, in step SL808, the port output processing is executed by the CALLS instruction. In the port output process, the test shooting test information stored in the test shooting test information area 633 in the work area 223 for non-specific control in the test shooting test process (step SL908 of the test shooting test execution process (FIG. 339)) is the test shooting that is an external device. The process for outputting to the test device is executed. As already described, the test-shooting test information is output to the test-shooting test apparatus via the relay board (not shown). When the test shot test device is not connected, the test shot test information generated in the test shot test process (step SL908 of the test shot test execution process (FIG. 339)) is cleared without being output.

In the port output processing in step SL808, the output information in the previous first timer interrupt processing (FIG. 338) is the same as the port output processing (step S8907) in the first timer interrupt processing (FIG. 133) of the 35th embodiment. When the setting is performed, the process for outputting to the various drive units 32b and 34b corresponding to the output information is executed. For example, when the information to switch the special electric prize winning device 32 to the open state is set, the output of the drive signal to the special electric drive unit 32b is started, and the information to switch to the closed state is set. Stops the output of the drive signal. Further, when the information for switching the universal electric accessory 34a of the second operation port 34 to the open state is set, the output of the drive signal to the drive unit 34b for the general electric power is started to switch to the closed state. When the information is set, the output of the drive signal is stopped.

After that, the reading process is executed by the CALLS instruction (step SL809). In the reading process, similar to the reading process (step S8908) in the first timer interrupt process (FIG. 133) of the 35th embodiment, signals other than the power failure signal and the winning signal are read, and the read information is read. Stored for use in future processing.

After that, a ball incoming detection process is executed by the CALLS command (step SL810). In the entry detection process, the signals received from the entry detection sensors 42a to 49a are read in the same manner as the entry detection process (step S309) of the timer interrupt process (FIG. 11) in the first embodiment. Based on the read result, the presence/absence of a ball entering the outlet 24a, the general winning opening 31, the special electric winning device 32, the first working opening 33, the second working opening 34, and the through gate 35 is specified.

Then, in steps SL811 to SL816, the same process as steps S8910 to S8915 of the first timer interrupt process (FIG. 133) in the thirty-fifth embodiment is executed by the CALLS instruction. After that, the total number display setting process (FIG. 343) is executed by the CALLS command (step SL817). In the total number display setting process, settings are performed so that the above-described total number information is displayed on the first to fourth notification display devices 201 to 204. The details of the total number display setting process (FIG. 343) will be described later. Then, in steps SL818 to SL820, the same processing as steps S8916 to S8918 of the first timer interrupt processing (FIG. 133) in the thirty-fifth embodiment is executed by the CALLS instruction.

After that, the management execution process (FIG. 340) is executed by the CALLI instruction (step SL821), and the first timer interrupt process is ended. As described above, the management execution process (FIG. 340) is a process corresponding to non-specific control.

When the management execution process (FIG. 340) is executed by the CALLI instruction, the information in the flag register of the main CPU 63 is first saved in the stack area 222 for specific control. By saving the information of the flag register before the program of the management execution process (FIG. 340) is started, it is changed after the call of the management execution process (FIG. 340) or the start of the management execution process (FIG. 340). It is possible to save the information in the flag register in the state before the operation to the stack area 222 for specific control.

When the management execution process (FIG. 340) is executed by the CALLI instruction, the information of the flag register is saved in the stack area 222 for specific control, and then the first timer interrupt process (FIG. 338) and the second timer described later. The interrupt of the timer interrupt process (FIG. 346) is prohibited. This allows the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) corresponding to the specific control to be performed during the execution of the management execution process (FIG. 340) corresponding to the non-specific control. ) Can be prevented from being interrupted and started.

When the management execution processing (FIG. 340) is executed by the CALLI instruction, the information of the flag register is saved in the stack area 222 for specific control, and the first timer interrupt processing (FIG. 338) and the second timer interrupt are executed. After the interruption of the process (FIG. 346) is prohibited, the program corresponding to the management execution process (FIG. 340) described later is started.

In this way, the management execution process (FIG. 340) is executed by the CALLI instruction, so that the information of the flag register of the main CPU 63 is stored in the stack area 222 for specific control by one instruction (“CALLI”). It is possible to save and interrupt the interrupts of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) to start the program corresponding to the management execution process (FIG. 340) described later. Therefore, the instruction for saving the information in the flag register of the main CPU 63 to the stack area 222 for specific control and the interruption of the first timer interrupt processing (FIG. 338) and the second timer interrupt processing (FIG. 346) are prohibited. In order to execute the management execution process (FIG. 340), the first timer interrupt process (FIG. 340) is compared with the case where the command for starting the program of the management execution process (FIG. 340) is separately provided. The number of instructions set in the program corresponding to FIG. 338) can be reduced. As a result, the storage capacity in the main ROM 64 for storing the program corresponding to the first timer interrupt processing (FIG. 338) can be reduced.

FIG. 340 is a flowchart showing the management execution processing executed by the main CPU 63. The processes of steps SM101 to SM116 in the management execution process are executed in the main CPU 63 using the non-specific control program and the non-specific control data.

In steps SM101 to SM115, the same processes as steps S3901 to S3915 of the management execution process (FIG. 71) in the fifteenth embodiment are executed. Specifically, first, as "LDSP, Y(u+2)", Y(u+2) is set to the stack pointer of the main CPU 63 as a fixed address at the start of the non-specific control by the load instruction (step SM101). As described above, Y(u+2) is information on the last address in the stack area 224 for non-specific control.

Thereafter, as "LD (_WABUF), WA", the information of the WA register of the main CPU 63 is saved in the WA buffer set in the work area 223 for non-specific control by a load instruction (step SM102). Further, as "LD (_BCBUF), BC", the load instruction saves the information in the BC register of the main CPU 63 to the BC buffer set in the work area 223 for non-specific control (step SM103). Further, as "LD (_DEBUF), DE", the load instruction saves the information in the DE register of the main CPU 63 to the DE buffer set in the work area 223 for non-specific control (step SM104). Further, as "LD (_HLBUF), HL", the information of the HL register of the main CPU 63 is saved in the HL buffer set in the work area 223 for non-specific control by a load instruction (step SM105). Further, as "LD (_IXBUF), IX", the load instruction saves the information in the IX register of the main CPU 63 to the IX buffer set in the work area 223 for non-specific control (step SM106). Further, as "LD (_IYBUF), IY", the load instruction saves the information in the IY register of the main CPU 63 to the IY buffer set in the work area 223 for non-specific control (step SM107).

By executing the processing of step SM102 to step SM107, the WA register, BC register, DE register, and HL register, which are some of the general-purpose registers, auxiliary registers, and index registers existing in the main CPU 63, are registered. , IX register and IY register information can be saved in the corresponding buffers in the work area 223 for non-specific control. The WA register, BC register, DE register, HL register, IX register, and IY register are registers used in the check process (step SM108) corresponding to the non-specific control. By saving the information set in such registers in the work area 223 for non-specific control before executing the check processing (step SM108), the information in these registers used in the specific control is checked ( It becomes possible to evacuate before step SM108) is started. Therefore, even if these registers are overwritten during execution of the check process (step SM108), when the check process (step SM108) ends, the information saved in the work area 223 for non-specific control is restored to these registers. By doing so, it becomes possible to restore the state of these registers to the state corresponding to the specific control before the check processing (step SM108) is executed.

Further, instead of saving all information of various general-purpose registers, auxiliary registers, and index registers in the work area 223 for non-specific control, it is used in the check processing (step SM108) corresponding to the non-specific control. By selectively saving the information of the target WA register, BC register, DE register, HL register, IX register, and IY register to the work area 223 for non-specific control, the registers in the work area 223 for non-specific control are registered. It is possible to suppress the capacity to be reserved for saving the information of. Therefore, it is possible to save the register information as described above while securing a large capacity of the work area 223 for non-specific control that can be used in the check process (step SM108). Of course, various general-purpose registers, auxiliary registers, and index registers in the main CPU 63 other than the WA register, BC register, DE register, HL register, IX register, and IY register are checked (step SM108). ) Is stored and held until the check process (step SM108) ends and the process corresponding to the specific control is restarted.

Further, the register information is not saved in the non-specific control stack area 224 but is saved in the non-specific control work area 223, so that the capacity of the non-specific control stack area 224 can be reduced to that extent. It will be possible. Further, when the stack area 224 for non-specific control is used, the writing order of information is read first from the later information as described above. Therefore, the reading order of information is displaced due to some noise or the like. If this happens, all subsequent read order information will be restored to a different register. The probability of occurrence of such an event increases as the amount of information saved in the stack area 224 for non-specific control increases. On the other hand, by saving the information in the register in the work area 223 for non-specific control, it is possible to prevent the above event from occurring even when there is a large amount of information to be saved. ..

After performing the processing of steps SM102 to SM107, the check processing (FIG. 341) is performed (step SM108). When executing the check process, the program of the subroutine corresponding to the check process set in the non-specific control program is executed. However, when executing the program of the subroutine, management after execution of the check process is performed. Information for specifying the return address of the execution process (FIG. 340) is written in the stack area 224 for non-specific control by the push command. Then, when the check process (step SM108) is completed, the information for specifying the return address is read by the pop command, and the program is returned to the program of the management execution process (FIG. 340) indicated by the return address. Details of the check process (FIG. 341) will be described later.

After the check process is executed, Y(r+α) is set in the stack pointer of the main CPU 63 as a fixed address when returning to the specific control by a load instruction as “LDSP, Y(r+α)” (step SM109). ). The address of Y(r+α) is set as an address between Y(r+8) and Y(s) in the stack area 222 for specific control.

The amount of information stored in the stack area 222 for specific control is always constant immediately before the management execution processing subroutine is executed in step SL821 of the first timer interrupt processing (FIG. 338), and accordingly, the timing concerned. The information of the stack pointer (that is, the value of the stack pointer) of the main CPU 63 is constant. In this case, the information stored in the stack area 222 for specific control includes, for example, information on the return address of the first timer interrupt processing (FIG. 338) after the management execution processing (FIG. 340) is completed. The constant information of the stack pointer is Y(r+α). Therefore, when the management execution process (FIG. 340) corresponding to the non-specific control ends and the process returns to the process corresponding to the specific control, Y(r+α), which is the certain information, is stored in the main CPU 63. By setting the stack pointer, the information of the stack pointer can be restored to the information immediately before the process corresponding to the non-specific control is started. By thus setting the fixed information in the stack pointer, the information of the stack pointer is restored to the information immediately before the start of the management execution process (FIG. 340). It is not necessary to save the information of the stack pointer of the main CPU 63 corresponding to the specific control in the main RAM 65 before starting. Therefore, it is possible to reduce the processing load, and it is not necessary to secure an area for saving in the main RAM 65.

After that, the information saved in the WA buffer of the work area 223 for non-specific control is overwritten in the WA register of the main CPU 63 by the load instruction as "LD WA, (_WABUF)" (step SM110). Also, as "LD BC, (_BCBUF)", the load instruction overwrites the information saved in the BC buffer of the work area 223 for non-specific control in the BC register of the main CPU 63 (step SM111). Further, as "LD DE, (_DEBUF)", the information saved in the DE buffer of the work area 223 for non-specific control is overwritten in the DE register of the main CPU 63 by the load instruction (step SM112). Further, as "LD HL, (_HLBUF)", the information saved in the HL buffer of the work area 223 for non-specific control is overwritten in the HL register of the main CPU 63 by the load instruction (step SM113). Further, as "LD IX, (_IXBUF)", the information saved in the IX buffer of the work area 223 for non-specific control is overwritten in the IX register of the main CPU 63 by the load instruction (step SM114). Further, as "LDIY, (_IYBUF)", the information saved in the IY buffer of the work area 223 for non-specific control is overwritten in the IY register of the main CPU 63 by the load instruction (step SM115). By executing the processing of step SM110 to step SM115, processing corresponding to non-specific control is started for each information of the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63. It is possible to restore the information corresponding to the specific control immediately before.

After that, the RETI command is executed as "RETI" (step SM116), and the present management execution process is ended. By executing the RETI instruction, the information of the flag register saved in the stack area 222 for specific control before the execution of the management execution process (FIG. 340) is returned to the flag register of the main CPU 63, and the first The generation of the timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) is switched from the prohibited state to the permitted state. As a result, the information in the flag register of the main CPU 63 is restored to the information for executing the specific control, and the first timer interrupt process and the second timer interrupt process can be newly executed.

Since the configuration is such that the RETI instruction is executed, the information of the flag register saved in the stack area 222 for specific control before the execution of the management execution processing by the one instruction (“RETI”) is used as the flag register of the main CPU 63. It is possible to return to the state described above, and it is possible to switch from the state in which the generation of the first timer interrupt processing (FIG. 338) and the generation in the second timer interrupt processing (FIG. 346) are prohibited to the state permitted. Therefore, an instruction for returning the information of the flag register saved in the stack area 222 for specific control to the flag register of the main CPU 63 before the execution of the management execution process, the first timer interrupt process (FIG. 338), and Compared with the case where an instruction for switching from the state in which the generation of the second timer interrupt processing (FIG. 346) is prohibited to the state in which the second timer interrupt processing is permitted is separately provided, the instruction set in the program corresponding to the management execution processing The number can be reduced. As a result, the storage capacity of the main ROM 64 for storing the program corresponding to the management execution process can be reduced.

As described above, the execution of the RETI instruction permits the generation of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346). Therefore, if the RETI instruction is executed in the situation where the processing corresponding to the non-specific control remains, the first timer interrupt which is the processing corresponding to the specific control in the situation where the processing corresponding to the non-specific control is executed. The process (FIG. 338) or the second timer interrupt process (FIG. 346) is interrupted and activated. On the other hand, since the RETI instruction is executed in step SM116, which is the last step of the management execution process (FIG. 340) that is the process corresponding to the non-specific control, the process corresponding to the non-specific control is performed. While preventing the first timer interrupt process (FIG. 338) or the second timer interrupt process (FIG. 346), which is the process corresponding to the specific control, from being interrupted and activated in the running state, the main CPU 63 It is possible to return to the first timer interrupt process (FIG. 338) that is a process corresponding to the specific control in a state where the information in the flag register has returned to the information for executing the specific control.

FIG. 341 is a flow chart showing the check processing executed by calling the program of the subroutine in step SM108 of the management execution processing (FIG. 340). Note that the processing of steps SM201 to SM206 in the check processing, including the processing of the subroutine, is executed in the main CPU 63 using the non-specific control program and non-specific control data. When executing the processing of the subroutine, the information on the return address after the execution of the processing of the subroutine is written in the storage area corresponding to the current value of the stack pointer of the main CPU 63 in the stack area 224 for non-specific control. At the same time, the value of the stack pointer is updated to the address information of the storage area to be stored in the next order. When the processing of the subroutine is completed, the information of the return address is read from the storage area corresponding to the value of the current stack pointer of the main CPU 63, which corresponds to the value of the previous order, and the information of the return address is corresponded to. While returning to the program, the value of the stack pointer is updated to the information of the address of the storage area from which the information of the return address is read.

In the check process (FIG. 341), if the front door frame 14 is in the open state (step SM201: YES), the result calculation process (step) to be described later (step SM201) is not performed and the normal ball management process (step SM204) is not executed. SM205) and display processing (step SM206) are executed. As already described in the fifteenth embodiment, since the game area PA is formed by the space defined by the back surface of the window panel 52 provided on the front door frame 14 and the front surface of the game board 24 in the front and rear, When the door frame 14 is opened, the game area PA is opened toward the front, and even if a game ball is shot toward the game area PA in that situation, the game ball will be in the game area PA. It cannot flow normally. Further, when the game balls enter the ball entrance portions 24a, 31 to 34 in a state where the front door frame 14 is in the open state, the game hall manager may perform maintenance or trouble elimination. This is a case where the front door frame 14 is opened and game balls enter due to care. Since the entry of such a game ball is not the entry of the game ball in the execution state of the regular game, it is not necessary to manage the entry of such a game ball. Therefore, in the check process, when the front door frame 14 is in the open state as described above, the normal entry management process (step SM204) is not executed.

On the other hand, when the front door frame 14 is not in the open state (step SM201: NO), it is determined whether or not it is in the opening/closing execution mode (step SM202), and when it is not in the opening/closing execution mode (step SM202: NO). Determines whether it is in the high frequency support mode (step SM203). When it is in the opening/closing execution mode (step SM202: YES) or in the high-frequency support mode (step SM203: YES), the result calculation process is executed without executing the normal entrance management process (step SM204). (Step SM205) and display processing (step SM206) are executed. On the other hand, when the front door frame 14 is in the closed state and is neither in the open/close execution mode nor the high frequency support mode (step SM201 to step SM203: NO), a normal entrance management process is executed (step SM204). ..

In the normal entrance management process (step SM204), the same process as the normal entrance management process (FIG. 74) in the fifteenth embodiment is executed. Specifically, when it is determined that one gaming ball has been detected by the first winning opening detection sensor 42a (step S4101: YES), one gaming ball is detected by the second winning opening detection sensor 43a. When it is determined that the game ball is detected (step S4103: YES), or when one game ball is detected by the third winning hole detection sensor 44a (step S4105: YES), the value of the normal general winning counter 231a Is incremented by 1 (step S4102, step S4104, step S4106). Further, when it is determined that one gaming ball is detected by the special electricity detection sensor 45a (step S4107: YES), the value of the normal special electricity prize counter 231b is incremented by 1 (step S4108), and the first working opening When it is determined that one gaming ball is detected by the detection sensor 46a (step S4109: YES), the value of the normal first operation counter 231c is incremented by 1 (step S4110), and the second operation opening detection sensor When it is determined that one gaming ball is detected at 47a (step S4111: YES), the value of the normal second operation counter 231d is incremented by 1 (step S4112), and the outlet detection sensor 48a outputs 1 When it is determined that one game ball has been detected (step S4113: YES), the value of the normal out counter 231e is incremented by 1 (step S4114).

By executing the normal ball management process (step SM204) as described above, the number of game balls entering the general winning opening 31 in a situation where neither the open/close execution mode by the jackpot result nor the high frequency support mode Is measured using the normal general prize counter 231a, the number of game balls entered into the special electric prize device 32 is measured using the normal special electric prize counter 231b, and the game to the first working port 33 is performed. The number of balls entering the ball is measured by using the normal first operation counter 231c, the number of balls entering the game ball into the second operating port 34 is measured by using the normal second operation counter 231d, The number of game balls entering the out port 24a is measured by using the normal out counter 231e. As a result, the main CPU 63 can grasp the entry history into each entry portion 24a, 31 to 34 in a situation in which neither the open/close execution mode nor the high frequency support mode based on the jackpot result.

Returning to the explanation of the check process (FIG. 341), if a positive determination is made in any of steps SM201 to SM203 or if the process of step SM204 is performed, the result calculation process is executed (step SM205). .. FIG. 342 is a flowchart showing the result calculation process. The processes of step SM301 to step SM315 in the result calculation process are executed using the non-specific control program and the non-specific control data in the main CPU 63.

In the result calculation process, first, it is determined whether or not "1" is set in the shift wait flag provided in the work area 223 for non-specific control (step SM301). The shift wait flag is a flag that allows the main CPU 63 to know that the data shift process (step SM302) should be executed at the start of the result calculation process (FIG. 342). In the shift wait flag, the total number of game balls discharged from the game area PA in a situation where the value of the management start flag is "0" and is neither the open/close execution mode due to the jackpot result nor the high frequency support mode. When the total number of game balls supplied to the game area PA reaches the management start reference number of 300, "1" is set in step SM311 described later. In addition, the shift wait flag has a total number of game balls discharged from the game area PA in a situation where neither the open/close execution mode due to the big hit result nor the high frequency support mode (that is, the total number of game balls supplied to the game area PA). When the (number) has reached the shift reference number of 60,000, “1” is set in step SM317 described later.

When an affirmative determination is made in step SM301, data shift processing is executed (step SM302). In the present embodiment, the latest base value is calculated by executing the later-described aggregate division process (FIG. 349) in the residual process (FIG. 347) described later, and the calculated base value is used for non-specific control. It is stored in the current area 311 in the work area 223 of FIG. In addition, in the present embodiment, after the first timer interrupt process (FIG. 338) is finished and before the next processing time of the first timer interrupt process (FIG. 338) is started, the residual process (FIG. The execution period of the first timer interrupt process (FIG. 338) and the execution period of the residual process (FIG. 347) are adjusted so that the processes of steps SM801 to SM808 in 347) are executed at least once. Therefore, when the first timer interrupt process (FIG. 338) is completed while the shift wait flag is set to “1”, the next process cycle of the first timer interrupt process (FIG. 338) is started. During this period, the final base value in the calculation period ended this time is stored in the current area 311. For this reason, the data shift processing (step SM302) is performed in a state where the final base value in the calculation period ended this time is stored in the current area 311.

In the data shift processing in step SM302, the current area 311 and the first history in the calculation result storage area 234 are similar to the data shift processing (steps S8607 and S8614 in the result calculation processing (FIG. 130)) in the thirty-fifth embodiment. The information stored in the area 312, the second history area 313, and the third history area 314 is changed to the second history area 313→the third history area 314, the first history area 312→the second history area 313, the current area 311→the third history area 313. It shifts in the order of 1 history area 312. As a result, the final base value in the calculation period two times before is stored in the third history area 314 as the final base value in the calculation period three times before, and the final base value in the calculation period one time before. Is stored in the second history area 313 as the final base value in the calculation period two times before, and the last calculated base value in the current calculation period is calculated as the final base value in the calculation period one time before. One history area 312 is stored. In the data shift processing, the LDIR instruction is used when the above information shift is performed. In the LDIR instruction, the information stored in the storage area is shifted (copied) to the storage area by designating the address of the storage area of the information and the address of the storage area of the information. Becomes Further, in the data shift processing in step SM306, the current area 311 is cleared to "0" after performing the above-described information shift processing.

However, in the situation where the value of the management start flag is "0" and neither the opening/closing execution mode due to the big hit result nor the high frequency support mode, the total number of game balls discharged from the game area PA (that is, the game area) If the shift wait flag is set to "1" based on the fact that the total number of game balls supplied to the PA has reached the management start reference number of 300, the first to the first Since the base value information is not stored in the 3 history areas 312 to 314, the first history area 312 of the final base value of the calculation period is substantially set in the situation where “1” is not set in the management start flag. Only the shift to.

After that, the shift wait flag is cleared to "0" (step SM303). As a result, the state where the execution of the data shift process (step SM302) is on standby is released. When a negative determination is made in step SM301, or when the process of step SM303 is executed, the total payout amount calculation process is executed (step SM304). In the calculation process of the total payout amount, the normal general prize winning counter 231a, the normal special electric prize counter 231b, and the normal special winning counter 231a in the normal counter area 231 (FIG. 336(a)) of the work area 223 for non-specific control. Based on the values of the 1-operation counter 231c and the normal second-operation counter 231d, the total payout number of game balls in a situation that is neither the opening/closing execution mode or the high-frequency support mode based on the jackpot result is calculated. The calculation method of the total payout number is as described above.

Then, the total payout amount information, which is the information on the total payout amount calculated in step SM304, is stored in the total payout amount area 632 in the work area 223 for non-specific control (step SM305). As described above, the total payout amount area 632 is a counter in which the total payout amount information, which is numerical information indicating the total payout amount of the game balls in a situation that is neither the opening/closing execution mode by the jackpot result nor the high frequency support mode, is stored. Is.

After that, arithmetic processing for the total number is executed (step SM306). In the calculation processing of the total number, the total number of game balls discharged from the game area PA in a situation where neither the open/close execution mode due to the jackpot result nor the high-frequency support mode (that is, the total number of game balls supplied to the game area PA). ) Is calculated. Specifically, the total number data is calculated by summing the values of the various counters 231a to 231e in the normal counter area 231. As described above, the total number information is 2-byte numerical value information that is any of “0” to “65535”. Then, the total number data calculated in step SM306 is stored in the total number area 631 in the work area 223 for non-specific control (step SM307).

After that, in Steps SM308 to SM310, the same processing as Step S8603, Step S8605 and Step S8606 of the result calculation processing (FIG. 130) in the 35th embodiment is executed. Specifically, it is determined whether the management start flag provided in the work area 223 for non-specific control is set to "1" (step SM308). As already described in the thirty-fifth embodiment, the management start flag has a value of “0” when the supply of operating power to the pachinko machine 10 is started for the first time after the pachinko machine 10 is manufactured. Further, when the work area 223 for non-specific control is also initialized by clearing "0" including the management start flag, the value of the management start flag becomes "0". The total number of game balls discharged from the game area PA in a situation where the management start flag has a value of "0" and is neither the open/close execution mode due to the big hit result nor the high frequency support mode (that is, in the game area PA When the total number of supplied game balls is 300, which is the management start reference number, "1" is set in the management start flag. When the management start flag is set to "1", the values of the various counters 231a to 231e in the normal counter area 231 are cleared to "0" and a new base value calculation period is started. As a result, the influence of the operation check at the shipping stage of the pachinko machine 10 can be made difficult to reach the base value in the situation where a normal game is played after the pachinko machine 10 is shipped.

After that, it is determined whether the total number calculated in the total number calculation process (step SM306) is more than the management start reference number of 300 (step SM309), and the total number is the management start reference. When the number is larger than the number (step SM309: YES), "1" is set to the management start flag in the work area 223 for non-specific control (step SM310). As a result, in the subsequent result calculation process (FIG. 342), an affirmative determination is made in step SM308, and the processes in step SM313 and thereafter are executed.

After performing the processing of step SM310, "1" is set to the shift wait flag in the work area 223 for non-specific control (step SM311). As a result, in the processing cycle next to the result calculation processing (FIG. 342), an affirmative determination is made in step SM301, and the above-described data shift processing (step SM302) is executed. After that, clearing processing of various counters is executed (step SM312). In the clearing process, all the counters 231a to 231e in the normal counter area 231 are cleared to "0".

When a positive determination is made in step SM308, it is determined whether or not the total number calculated in the total number calculation process (step SM306) is more than the initial reference number of 6000 (step SM313). ). If a negative determination is made in step SM313, "1" is set to the calculation initial flag in the work area 223 for non-specific control (step SM314), and if a positive determination is made in step SM313, the calculation initial flag is set. Is cleared to "0" (step SM315). As already described, the calculation initial flag is the total of the game balls discharged from the game area PA in a situation in which the base value calculation period is newly started and neither the open/close execution mode due to the jackpot result nor the high frequency support mode is present. This is a flag for the main CPU 63 to specify whether or not the number (that is, the total number of game balls supplied to the game area PA) has reached the initial reference number (specifically, 6000).

When the process of step SM314 is executed or when the process of step SM315 is executed, it is calculated by the total number calculation process (step SM306) based on the total number data stored in the total number area 631. It is determined whether or not the total number is the shift reference number of 60000 or more (step SM316), and if the total number is the shift reference number or more (step SM316: YES), the work for non-specific control is performed. The shift wait flag in the area 223 is set to "1" (step SM317). As a result, in the processing cycle next to the result calculation processing (FIG. 342), an affirmative determination is made in step SM301, and the above-described data shift processing (step SM302) is executed. After that, clear processing of various counters is executed (step SM318), and this result calculation processing ends. In the various counter clearing process, similarly to the various counter clearing process in step SM312, all the counters 231a to 231e in the normal counter area 231 are cleared to "0".

As described above, when the base value calculation period ends, "1" is set in the shift wait flag and the values of the various counters 231a to 231e in the normal counter area 231 are cleared to "0". By resetting the values of the various counters 231a to 231e in the normal counter area 231 at the processing times when the base value calculation period has ended and starting the next calculation period, the game area PA is switched at the timing when the base value calculation period switches. It is possible to avoid a situation in which the game balls discharged from are no longer measured. In addition, at the processing times when the base value calculation period ends, the shift wait flag is set to "1" to end the result calculation process, and the result calculation is started in a state where the shift wait flag is set to "1". The data shift process is executed in the next processing cycle. After the first timer interrupt process (FIG. 338) is completed, the residual process (FIG. 347) described below is executed at least once until the next process time of the first timer interrupt process is started. Therefore, the data shift process (step SM302) can be executed while the final base value in the completed calculation period is stored in the current area 311. Accordingly, the base value shifted from the current area 311 to the first history area 312 in the data shift process (step SM302) can be set as the final base value in the calculation period ended this time.

Returning to the explanation of the check process (FIG. 341), after the result calculation process is executed in step SM205, the display process described later is executed (step SM206), and the check process is ended.

Next, prior to the description of the display processing (FIG. 344) executed by the main CPU 63, the total number display setting processing executed in step SL817 of the first timer interrupt processing (FIG. 338) will be described with reference to FIG. This will be described with reference to the flowchart. The program corresponding to the total number display setting process is set to the specific control program.

In the total number display setting process, first, based on the result of the reading process (step SL809) in the first timer interrupt process (FIG. 338), it is determined whether or not the reset button 68c is pressed (step SM401). .. As already described in the first embodiment, the reset button 68c is provided with a sensor (not shown), and the sensor detects whether or not the reset button 68c is pressed. Then, the main CPU 63 specifies whether or not the reset button 68c is pressed based on the detection result from the sensor. In step SM401, when the rising of the signal received from the detection sensor for detecting the state of the reset button 68c in the reading process (step SL809) from the OFF state to the ON state is detected, the reset button 68c is pressed. It is determined that it has been performed.

When an affirmative determination is made in step SM401, it is determined whether or not "1" is set in the setting confirmation display flag provided in the specific control work area 221 (step SM402). Similar to the thirty-fifth embodiment, the setting confirmation display flag allows the main CPU 63 to specify whether or not the main CPU 63 is executing the setting confirmation process (FIG. 136). It is a flag. The situation in which "1" is set in the setting confirmation display flag corresponds to the situation in which the setting confirmation process (Fig. 136) is being executed. When "1" is not set in the setting confirmation display flag (step SM402: NO), it is determined whether or not "1" is set in the setting update display flag provided in the work area 221 for specific control. A determination is made (step SM403). Similar to the thirty-fifth embodiment, the setting update display flag is used by the main CPU 63 to specify whether or not the setting value update processing (FIG. 137) is being executed by the main CPU 63. It is a flag. The situation where the setting update display flag is set to "1" corresponds to the situation where the setting value updating process (Fig. 137) is being executed.

When a negative determination is made in step SM403, it is determined whether the value of the display target counter in the work area 223 for non-specific control is "0" (step SM404). As already described in the 35th embodiment, the display target counter is stored in each of the current state area 311, the first history area 312, the second history area 313, and the third history area 314 in the calculation result storage area 234. This is a counter for the main CPU 63 to specify the base value to be notified in the first to fourth notification display devices 201 to 204 among the base values. Specifically, when the value of the display target counter is “0”, the base value stored in the current area 311 becomes the notification target, and when the value of the display target counter is “1”, the first history area When the base value stored in 312 is the notification target and the value of the display target counter is “2”, the base value stored in the second history area 313 is the notification target and the value of the display target counter is “3”. , The base value stored in the third history area 314 becomes the notification target. As already described in the fifteenth embodiment, the work area 223 for non-specific control cannot store information when the processing corresponding to the specific control is executed by the main CPU 63. Reading is possible. Therefore, it is possible to determine whether or not the value of the display target counter in the work area 223 for non-specific control is "0" in step SM404 executed using the program for specific control.

If an affirmative determination is made in step SM404, the reset button is displayed in the situation where the most recent base value stored in the current area 311 is being displayed on the first to fourth notification display devices 201 to 204. Since this means that the pressing operation of 68c has been performed, "1" is set to the total number display operation flag provided in the work area 221 for specific control (step SM405), and this total number display setting process is performed. To finish. The total number display operation flag is a flag that allows the main CPU 63 to know that the display of the total number information should be started on the first to fourth notification display devices 201 to 204.

As described above, the reset button 68c is displayed in the total number display operation flag in the situation where the latest base value stored in the current area 311 is displayed on the first to fourth notification display devices 201 to 204. "1" is set when the pressing operation is performed. By setting the total number display operation flag to "1" in step SM405, an affirmative determination is made in step SM601 of the total number display process (FIG. 345) described below, and the work area 223 for non-specific control is executed. “1” is set to the total number display flag provided in the above. The total number display flag is a flag that enables the main CPU 63 to know that the first to fourth notification display devices 201 to 204 should display the total number information. Then, by setting the total number display flag to “1”, the process (the process of step SM605) for displaying the total number information on the first to fourth notification display devices 201 to 204 is executed. Will be done.

On the other hand, when a negative determination is made in step SM401, it is determined whether or not "1" is set in the total number display operation flag in the specific control work area 221 (step SM406). When the total number display operation flag is set to "1" (step SM406: YES), it is determined whether the total number display flag in the work area 223 for non-specific control is set to "1". A determination is made (step SM407). As described above, in the work area 223 for non-specific control, when the process corresponding to the specific control is executed by the main CPU 63, the information cannot be stored, but the information can be read. Therefore, it is possible to determine whether or not "1" is set in the total number display flag in the work area 223 for non-specific control in step SM407 executed using the program for specific control.

When an affirmative determination is made in step SM407, the total number display operation flag is cleared to "0" (step SM408), and this total number display setting process ends. As described above, the value of the total number display operation flag in the specific control work area 221 is set to "1" in the total number display flag in the non-specific control work area 223 and the first to fourth notifications are performed. “0” is cleared when the display of the total number information is started on the display devices 201 to 204. Thereby, it is possible to prevent the display of the total number information from being repeatedly started on the first to fourth notification display devices 201 to 204 based on one operation of the reset button 68c.

Next, the display processing executed by the main CPU 63 will be described with reference to the flowchart in FIG. The display process is executed in step SM206 of the check process (FIG. 341). Further, the processing of steps SM501 to SM518 in the display processing is executed using the non-specific control program and non-specific control data in the main CPU 63.

In the display process, first, it is determined whether or not the management start flag in the work area 223 for non-specific control is set to "1" (step SM501), and when the management start flag is set to "1". In (step SM501: YES), a total number display process is executed (step SM502).

FIG. 345 is a flowchart showing the processing for displaying the total number. The program corresponding to the total number display process is set to the non-specific control program.

In the total number display processing, it is first determined whether or not "1" is set in the total number display operation flag in the work area 221 for specific control (step SM601). As already described in the fifteenth embodiment, the work area 221 for specific control cannot store information when the process corresponding to the non-specific control is executed by the main CPU 63. Reading is possible. Therefore, it is possible to determine whether or not the total number display operation flag in the specific control work area 221 is set to "1" in step SM601 executed using the non-specific control program. ..

When an affirmative determination is made in step SM601, "1" is set to the total number display flag provided in the work area 223 for non-specific control (step SM602). As described above, the total number display flag indicates that the total number information (upper four digits of the total number data) should be displayed on the first to fourth notification display devices 201 to 204. This is a flag that can be grasped by the main CPU 63.

After that, a switching timing counter setting process is executed (step SM603). In the setting process of the switching timing counter, a value that enables the switching timing counter provided in the work area 223 for non-specific control to grasp the switching timing of the next notification target is displayed in the display continuation period (specifically, 5 seconds). Set the corresponding value. In the switching timing counter in the present embodiment, the display continuation period (specifically, 5 seconds) of the base value or the total number information which is the notification target in the first to fourth notification display devices 201 to 204 has elapsed. This is a counter for the main CPU 63 to specify this. As described above, the continuous display period of the total number information is 5 seconds like the continuous display period of the base value.

When a negative determination is made in step SM601 or when the processing of step SM603 is performed, it is determined whether or not "1" is set in the total number display flag (step SM604). When an affirmative determination is made in step SM604, the display data of the total number information corresponding to the total number data stored in the total number area 631 of the work area 223 for non-specific control is displayed in the display target setting area 276. After setting (step SM605), the setting process for displaying the total number of pieces is ended. As described above, as the display data of the total number information, the display corresponding to the tens place digit in the total number data (numerical information of any of “0” to “65535”) is displayed on the first notification display device 201. Display data for performing the display data, display data for causing the second notification display device 202 to perform display corresponding to the number of thousands in the total number, and display corresponding to the number of hundreds in the total number. It includes display data for causing the third notification display device 203 to display, and display data for causing the fourth notification display device 204 to perform display corresponding to the tens digit in the total number.

As described above, the display duration of the total number information (specifically 5 seconds) is grasped by using the switching timing counter for grasping the display duration of the base value (concretely 5 seconds). To be done. As a result, as compared with a configuration in which a timing counter for grasping the display duration time of the total number information (specifically, 5 seconds) is provided separately from the switching timing counter, the display duration time of the total number information (specifically, Is 5 seconds), and the configuration for making it possible to grasp the time is simplified.

Returning to the description of the display process (FIG. 344), after the total number display process is executed in step SM502, the value of the switching timing counter in the work area 223 for non-specific control is decremented by 1 (step SM503). Then, by determining whether or not the value of the switching timing counter after the subtraction of 1 is "0", the base value or the total number information which is the current notification target is displayed after the notification target. It is determined whether or not a continuation period (specifically, 5 seconds) has elapsed (step SM504). When an affirmative determination is made in step SM504, it is determined whether or not "1" is set in the total number display flag provided in the work area 223 for non-specific control (step SM505).

When a negative determination is made in step SM505, that is, when the current notification target is any base value, the process proceeds to step SM506. In Step SM506 to Step SM508, the same processing as Step S8704 to Step S8706 of the display processing (FIG. 131) in the 35th embodiment is executed. Specifically, first, the display target counter is updated (step SM506). In the update process, the value of the display target counter is incremented by 1. When the value of the display target counter after adding 1 exceeds the maximum value of "3" (step SM507: YES), the value of the display target counter is cleared to "0" (step SM508). In this way, the base value of any one of the current area 311, the first history area 312, the second history area 313, and the third history area 314 is displayed on the first to fourth notification display devices 201 to 204. When the display continuation period (specifically, 5 seconds) ends in the situation, the predetermined order (current area 311→first history area 312→second history area 313→third history area 314 is set. ), the base value to be displayed is updated. Then, the switching of the base value to be notified in the predetermined order is repeated.

On the other hand, if a positive determination is made in step SM505, that is, if the current notification target is total number information, the total number display flag is cleared to "0" (step SM509), and the process proceeds to step SM508. In step SM508, as described above, the value of the display target counter is cleared to "0". As a result, the base value of the current area 311 becomes the notification target in the first to fourth notification display devices 201 to 204. In this way, when the display period of the total number information in the first to fourth notification display devices 201 to 204 ends, in the first to fourth notification display devices 201 to 204, the base value of the current area 311 is changed. Display is performed. For this reason, the manager of the game hall who has grasped the total number information based on the displays of the first to fourth notification display devices 201 to 204 should check the latest base value again after the display of the total number information is finished. You can

When a negative determination is made in step SM507 or when the processing of step SM508 is performed, the switching timing counter setting processing is executed (step SM510). In the setting processing of the switching timing counter, the switching timing counter of the work area 223 for non-specific control is set to a value corresponding to the display continuation period (specifically, 5 seconds) as a value corresponding to the switching timing of the next notification target. To set. As a result, the base value display period on the first to fourth notification display devices 201 to 204 becomes 5 seconds.

When a negative determination is made in step SM504 or the processing of step SM510 is executed, it is determined whether or not "1" is set in the total number display flag in the work area 223 for non-specific control. Yes (step SM511). When an affirmative determination is made in step SM511, it means that the current notification target in the first to fourth notification display devices 201 to 204 is the total number information, and thus the main display processing is ended as it is. .. In this case, based on the display data of the total number information set in the display target setting area 276 in step SM605 of the total number display process (FIG. 345), the first to fourth notification display devices 201 to 204 are provided. The total number information is displayed at.

On the other hand, if "1" is not set in the total number display flag (step SM511: NO), the process proceeds to step SM512. In steps SM512 to SM517, the same processing as steps S8708 to S8713 of the display processing (FIG. 131) in the thirty-fifth embodiment is executed. Specifically, first, display type data corresponding to the value of the display target counter in the work area 223 for non-specific control is set in the display target setting area 276 (step SM512). As already described in the thirty-fifth embodiment, the display type data is displayed on the first notification display device 201 as a display indicating that the notification target of the first to fourth notification display devices 201 to 204 is the base value. Which of the present area 311, the first history area 312, the second history area 313, and the third history area 314 in the calculation result storage area 234 corresponds to the display data for execution and the base value to be notified. And display data for causing the second notification display device 202 to display.

After that, the base value is read from an area corresponding to the value of the display target counter among the current area 311, the first history area 312, the second history area 313, and the third history area 314 in the calculation result storage area 234, and the read base is read. The calculation result data corresponding to the first digit of the decimal point and the second digit of the decimal point in the value are set in the display target setting area 276 (step SM513). The calculation result data of the base value includes display data for causing the third notification display device 203 to display the number corresponding to the first decimal place of the base value to be notified, and the decimal point second to the base value to be notified. Display data for causing the fourth annunciator display device 204 to perform a display corresponding to the digit of the place.

As described above, display data including display type data and calculation result data is set in the display target setting area 276. The display data is transmitted to the fifth display circuit 265 via the display IC 266 in the second timer interrupt process (FIG. 346) described later, so that the display is performed on the first to fourth notification display devices 201 to 204. The display corresponding to the data is performed.

Then, based on the value of the display target counter in the work area 223 for non-specific control, it is determined whether or not the base value of the current area 311 is the notification target (step SM514), and the work area for non-specific control is performed. It is determined whether or not the operation initial flag in 223 is set to "1" (step SM515). When both the step SM513 and the step SM514 are affirmatively determined, from the game area PA in a situation where neither the open/close execution mode by the jackpot result nor the high-frequency support mode has occurred since the base value calculation period was newly started. In the situation where the total number of discharged game balls (that is, the total number of game balls supplied to the game area PA) does not reach the initial reference number (specifically, 6000), it is stored in the current area 311. Since the latest base value has been notified, the initial display flag provided in the work area 223 for non-specific control is set to "1" (step SM516), and this display process is terminated. To do. On the other hand, when a negative determination is made in either step SM514 or step SM515, the initial display flag is cleared to "0" (step SM517), and this display processing is ended.

The initial display flag is used for the first notification display device 201 to notify that the base value is the initial calculation base value after the start of the calculation period in the situation where the base value of the current area 311 is the notification target. And a flag for the main CPU 63 to specify that the second notification display device 202 should be displayed in a blinking manner. If it is specified in the second timer interrupt process (FIG. 346) described later that the initial display flag is set to “1”, the display data stored in the display target setting area 276 is simply transmitted to the display IC 266. When the first to fourth notification display devices 201 to 204 are caused to perform the display corresponding to the display data, the first notification display device 201 and the second notification display device 202 are displayed in blinking and the third The notification display device 203 and the fourth notification display device 204 are lit and displayed. When it is specified in the second timer interrupt process (FIG. 346) described later that the initial display flag is not set to “1”, the display corresponding to the display data stored in the display target setting area 276 is displayed. When all of the first to fourth notification display devices 201 to 204 are performed, all of the first to fourth notification display devices 201 to 204 are lit and displayed.

On the other hand, if "1" is not set in the management start flag provided in the work area 223 for non-specific control and a negative determination is made in step SM501, regardless of the value of the display target counter, from the current area 311 The base value is read out, and the calculation result data corresponding to the first decimal place number and the second decimal place digit in the read base value are set in the display target setting area 276 (step SM518). By transmitting the display data corresponding to the calculation result data to the display IC 266, the first decimal place number in the base value of the current area 311 is displayed on the third notification display device 203, and the base of the current area 311 is displayed. The second digit of the decimal point in the value is displayed on the fourth annunciator display device 204. With the above configuration, when the management start flag is not set to "1", the base value in the past calculation period is not notified, and only the latest base value calculated in the current calculation period is reported. Is notified. As already described in the thirty-fifth embodiment, when the base value is notified in a situation where "1" is not set in the management start flag, the first notification display device 201 and the second notification The display content of the display device 202 is different from that displayed when the base value is notified in the situation where the management start flag is set to "1".

Next, the second timer interrupt process executed by the main CPU 63 will be described with reference to the flowchart of FIG. 346. As described above, the second timer interrupt process is activated in the second interrupt cycle (2 milliseconds). Further, the processing of steps SM701 to SM716 in the second timer interrupt processing is executed by the main CPU 63 using the program for specific control and the data for specific control.

In the second timer interrupt process, first, as “DI”, the DI command is used to inhibit the interrupts of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) (step SM701). Since the generation of the first timer interrupt process (FIG. 338) is prohibited, the first timer interrupt process (FIG. 346) can be used for the first timer interrupt process (specifically, 4 milliseconds) even if the first interrupt cycle (specifically, 4 milliseconds) has elapsed. It is possible to prevent the timer interrupt processing (FIG. 338) from being interrupted and activated. Further, since the generation of the second timer interrupt process (FIG. 346) is prohibited, the second interrupt cycle (specifically, 2 milliseconds) may be temporarily passed during the execution of the second timer interrupt process (FIG. 346). Even if it happens, it is possible to prevent the second timer interrupt processing (FIG. 346) from being redundantly activated.

Then, in steps SM702 to SM706, the same processing as steps S9002 to S9006 of the second timer interrupt processing (FIG. 134) in the thirty-fifth embodiment is executed. Specifically, first, the checking counter is updated (step SM702). In the updating process of the checking counter, when the value of the checking counter provided in the work area 221 for specific control is 1 or more, the value of the checking counter is decremented by 1. Similar to the thirty-fifth embodiment, when the supply of operating power to the main CPU 63 is started, the display segments 321 to 324 provided in the first to fourth notification display devices 201 to 204 are normal. Until the initial check period (specifically, 5 seconds) elapses from the start of the process of step S8804 of the main process (FIG. 132) in order to allow the manager of the game hall to confirm whether or not the game light can be turned on. , The first to fourth notification display devices 201 to 204 perform a check display in which all the display segments 321 to 324 of the first to fourth notification display devices 201 to 204 are maintained in the light emitting state. (See FIG. 128(b)). The in-checking counter is a counter that enables the main CPU 63 to know that the initial checking period is in progress. When the checking counter is updated in step SM702 to measure the initial check period using the checking counter, the value of the checking counter is set to the second timer interrupt processing ( 346) will be periodically decremented each time it is activated.

Then, it is determined whether or not "1" is set in the setting update display flag in the work area 221 for specific control (step SM703). As described above, the setting update display flag is a flag for the main CPU 63 to specify whether the setting value update processing (FIG. 137) is being executed by the main CPU 63. As already described in the thirty-fifth embodiment, the set value updating process (FIG. 137) is performed when the supply of the operating power is started in the main process (FIG. 132) when the supply of the operating power to the main CPU 63 is started. Although the processing is executed in the situation where the processing is being executed, the second timer interrupt processing (FIG. 346) is interrupted and activated even in the situation where the processing at the start of supplying the operating power is being executed. Therefore, the second timer interrupt process (FIG. 346) is interrupted and activated even when the set value update process (FIG. 137) is being executed by the main CPU 63.

The situation in which the setting update display flag is set to "1" means that the main CPU 63 is executing the setting value update processing (FIG. 137) for the current processing time of the second timer interrupt processing (FIG. 346). It means that the processing time was interrupted and activated in some situations. When an affirmative decision is made in step SM703, a setting process for the fifth display data buffer 275 during the setting update is executed (step SM704). In the setting process, similar to step S9004 of the second timer interrupt process (FIG. 134) in the thirty-fifth embodiment, the setting values of the pachinko machine 10 are updated on the first to fourth notification display devices 201 to 204. The fifth display data buffer 275 stores display data for displaying the current status and the current setting value of the pachinko machine 10. As a result, the first to fourth notification display devices 201 to 204 perform a display indicating that the setting value is being updated and a display indicating the current setting value.

When a negative determination is made in step SM703, it is determined whether or not "1" is set in the setting confirmation display flag in the work area 221 for specific control (step SM705). As described above, the setting confirmation display flag is a flag for the main CPU 63 to specify whether or not the main CPU 63 is executing the setting confirmation process (FIG. 136). As already described in the thirty-fifth embodiment, the setting confirmation process (FIG. 136) is the process at the start of the supply of the operating power in the main process (FIG. 132) when the supply of the operating power to the main CPU 63 is started. However, the second timer interrupt process (FIG. 346) is interrupted and started even when the process at the start of supply of the operating power is being executed. The second timer interrupt process (FIG. 346) is activated by interruption even when the setting confirmation process (FIG. 136) is being executed by the main CPU 63.

The situation in which the setting confirmation display flag is set to "1" means that the main CPU 63 executes the setting confirmation processing (FIG. 137) for the current processing time of the second timer interrupt processing (FIG. 346). It means that the processing time was interrupted and activated in some situations. If an affirmative decision is made in step SM705, a setting process for the fifth display data buffer 275 during setting confirmation is executed (step SM706). In the setting process, similarly to step S9006 of the second timer interrupt process (FIG. 134) in the 35th embodiment, the set values of the pachinko machine 10 are confirmed on the first to fourth notification display devices 201 to 204. The fifth display data buffer 275 stores display data for displaying the current status and the current setting value of the pachinko machine 10. As a result, the first to fourth notification display devices 201 to 204 perform a display indicating that the setting value is being confirmed and a display indicating the current setting value.

When a negative determination is made in step SM705, it is determined whether or not the total number display flag in the work area 223 for non-specific control is set to "1" (step SM707). As described above, the total number display flag is a flag that allows the main CPU 63 to know that the first to fourth notification display devices 201 to 204 are in a state where the total number information should be displayed. is there.

When an affirmative determination is made in step SM707, a setting process for the fifth display data buffer 275 during the display of the total number is executed (step SM708). In the setting process, the display data of the total number information stored in the display target setting area 276 in the work area 223 for non-specific control is read, and the read display data of the total number information is read as the work area 221 for specific control. In the fifth display data buffer 275.

As described above, in the work area 223 for non-specific control, when the process corresponding to the specific control is executed by the main CPU 63, the information cannot be stored, but the information can be read. Therefore, it is possible to determine whether or not "1" is set in the total number display flag in the work area 223 for non-specific control in step SM707 executed by using the program for specific control. At the same time, it is possible to read the display data of the total number information stored in the display target setting area 276 in the work area 223 for non-specific control in step SM708 executed by using the program for specific control.

As described above, the display data of the total number information includes the display data for causing the first notification display device 201 to perform a display corresponding to the tens digit of the total number, and the thousands digit of the total number. Display data for causing the second notification display device 202 to perform a display, and display data for causing the third notification display device 203 to perform a display corresponding to the hundreds digit in the total number. The display data for causing the fourth notification display device 204 to perform a display corresponding to the tens digit in the total number is included. In step SM708, the display control of the first to fourth notification display devices 201 to 204 is performed according to the display data stored in the fifth display data buffer 275, whereby the first to fourth notification display devices 201 to 204 are performed. The total number information is displayed (displaying the upper 4 digits of the total number data).

If a negative determination is made in step SM707, normal setting processing (FIG. 135) is executed (step SM709). The processing contents of the setting processing at the normal time are as already described with reference to the flowchart of FIG. 135 in the 35th embodiment.

When the process of step SM704 is performed, the process of step SM706 is performed, the process of step SM708 is performed, or the process of step SM709 is performed, the process proceeds to step SM710. In Step SM710 to Step SM715, the same processing as Step S9008 to Step S9013 of the second timer interrupt processing (FIG. 134) in the 35th embodiment is executed.

When various signal transmission processing is executed in step SM715, "EI" is set by the EI instruction to permit generation of the first timer interrupt processing (FIG. 338) and the second timer interrupt processing (FIG. 346). (Step SM716), and the second timer interrupt processing is ended. This enables new execution of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346).

Next, the main processing executed by the main CPU 63 will be described. The program corresponding to the main process is set to the program for specific control.

In the main process of this embodiment, first, the same processes as steps S8801 to S8821 of the main process (FIG. 132) of the 35th embodiment are executed. In the main processing according to the present embodiment, after the return command is transmitted to the sound emission control device 81 in step S8821, the residual processing (FIG. 347) is executed.

FIG. 347 is a flowchart showing the residual processing. The program corresponding to the residual processing is set to the program for specific control. The address where the program corresponding to the residual processing is stored in the main ROM 64 (FIG. 67) is “RS_L”. “RS_L” is an address within the range of addresses X(1) to X(k+2) in the main ROM 64 described with reference to FIG. 67 in the fifteenth embodiment.

In the residual processing, first, as “DI”, the DI instruction is used to inhibit the interrupts of the first timer interrupt processing (FIG. 338) and the second timer interrupt processing (FIG. 346) (step SM801). Since the generation of the first timer interrupt process (FIG. 338) is prohibited, the first timer interrupt process is performed for the residual process (FIG. 347) even if the first interrupt cycle (specifically, 4 milliseconds) has elapsed. (FIG. 338) can be prevented from being interrupted and activated. Further, by prohibiting the generation of the second timer interrupt process (FIG. 346), even if the second interrupt cycle (specifically, 2 milliseconds) has elapsed, the second timer is used for the residual process (FIG. 347). It is possible to prevent the interrupt processing (FIG. 346) from being interrupted and activated.

Then, in step SM802 and step SM803, the same processing as step S8823 and step S8824 of the main processing (FIG. 132) in the thirty-fifth embodiment is executed. Specifically, in step SM802, random number initial value updating processing for updating the random number initial value counter CINI is executed, and in step SM803, fluctuation counter updating processing for updating the fluctuation type counter CS is executed. In these updating processes, the current numerical value information is read from the corresponding counter of the main RAM 65, the process of adding 1 to the read numerical value information is performed, and then the process of overwriting the counter of the reading source is executed. In this case, when the counter value exceeds the maximum value, each is cleared to "0".

After that, the setting monitoring process is executed by the CP command as "CP (IY+SETTEI), N_SETMAX" (step SM804). In the setting monitoring process, it is determined whether or not the set value of the pachinko machine 10 is normal by checking the value of the set value counter in the specific control work area 221. Specifically, when the value set in the set value counter is a value corresponding to any of "setting 1" to "setting 6", it is determined to be normal, and "setting 1" to "setting 6" If the value does not correspond to any of the above, it is determined to be the above.

After that, as "JRS F, FATAL", the game stop process is executed by the JRS command (step SM805). In the game stop process, when it is determined that the set value set in the set value counter is abnormal in the setting monitoring process in step SM804, "1" is set to the game stop flag in the specific control work area 221. To do. When the game stop flag is set to "1", an affirmative determination is made in step SL808 of the first timer interrupt process (FIG. 338), and the processes in steps SL809 to SL821 are not executed. As a result, when it is specified that the set value is abnormal, the progress of the game is stopped. Then, an abnormal command indicating that the set value is abnormal is transmitted to the voice light emission control device 81. Upon receipt of the abnormal command, the voice emission control device 81 causes the display light emitting unit 53 to emit light in a manner corresponding to the abnormal set value, and causes the speaker unit 54 to output the voice "Please change the setting." .. Moreover, the character image "Please change the setting." is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are ended when the supply of operating power to the pachinko machine 10 is stopped. However, even if the supply of the operating power to the pachinko machine 10 is temporarily stopped, the supply of the operating power to the pachinko machine 10 is restarted until the setting value updating process (step S8819) of the main process (FIG. 132) is executed. It may be configured such that the notification is continued in the case of being notified. The manager of the game hall, who has confirmed the above notification in the situation where the progress of the game is stopped, temporarily stops the supply of operating power to the pachinko machine 10 and then resumes the supply of operating power to the pachinko machine 10. When the setting is performed, the operation for performing the set value updating process (step S8819) is performed. This makes it possible to set a new setting value in the setting value updating process (step S8819) when a setting value abnormality occurs. In this way, by monitoring the abnormality of the set value in the residual process (FIG. 347), it is possible to monitor whether or not the set value is abnormal even in a situation where a game is being played. Become. Therefore, it is possible to prevent the game from being continued even if the set value is abnormal. Further, it becomes possible to increase the frequency of monitoring whether or not the set value is abnormal.

After that, the total division execution processing (FIG. 348) is executed by the CALLI instruction (step SM806). As described above, the total division execution process (FIG. 348) is a process corresponding to non-specific control.

When the total division execution processing (FIG. 348) is executed by the CALLI instruction, the information in the flag register of the main CPU 63 is first saved in the stack area 222 for specific control. By saving the information in the flag register before the program of the total division execution process (FIG. 348) is started, the call of the total division execution process (FIG. 348) and the start of the total division execution process (FIG. 348) are started. It is possible to save the information of the flag register in the state before the change in the above in the stack area 222 for specific control.

When the aggregate division execution process (FIG. 348) is executed by the CALLI instruction, the first timer interrupt process (FIG. 338) and the second timer interrupt process are performed after the flag register information is saved in the stack area 222 for specific control. The interrupt of (FIG. 346) is prohibited. As a result, the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 338) that are processes corresponding to the specific control are performed during the execution of the total division execution process (FIG. 348) that is the process corresponding to the non-specific control. It is possible to prevent 346) from being interrupted and activated.

When the total division execution processing (FIG. 348) is executed by the CALLI instruction, the information of the flag register is saved in the stack area 222 for specific control, and the first timer interrupt processing (FIG. 338) and the second timer are executed. After the interruption of the interruption processing (FIG. 346) is prohibited, the program corresponding to the aggregation/division execution processing (FIG. 348) described later is started.

In this way, the configuration in which the total division execution processing (FIG. 348) is executed by the CALLI instruction allows the information of the flag register of the main CPU 63 to be transferred to the stack area 222 for specific control by one instruction (“CALLI”). To interrupt the interrupts of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346), and start the program corresponding to the later-described aggregate division execution process (FIG. 348). .. Therefore, the instruction for saving the information in the flag register of the main CPU 63 to the stack area 222 for specific control and the interruption of the first timer interrupt processing (FIG. 338) and the second timer interrupt processing (FIG. 346) are prohibited. In order to execute the process corresponding to the non-specific control, the residual process (FIG. 347) is compared with the case where the command for starting the program of the total division operation (FIG. 348) is separately provided. ), the number of instructions set in the program corresponding to can be reduced. As a result, the storage capacity of the main ROM 64 for storing the program corresponding to the residual processing (FIG. 347) can be reduced.

FIG. 348 is a flowchart showing the total division execution processing executed by the main CPU 63. The processes of steps SM901 to SM916 in the total division execution process are executed by the main CPU 63 using the non-specific control program and the non-specific control data.

In steps SM901 to SM907, the same processing as steps S3901 to S3907 of the management execution processing (FIG. 71) in the fifteenth embodiment is executed. Specifically, first, as "LDSP, Y(u+2)", Y(u+2) is set to the stack pointer of the main CPU 63 as a fixed address at the start of non-specific control by a load instruction (step SM901). As described above, Y(u+2) is information on the last address in the stack area 224 for non-specific control.

Thereafter, as "LD (_WABUF), WA", the load instruction saves the information in the WA register of the main CPU 63 to the WA buffer set in the work area 223 for non-specific control (step SM902). Further, as "LD (_BCBUF), BC", the load instruction saves the information of the BC register of the main CPU 63 to the BC buffer set in the work area 223 for non-specific control (step SM903). Further, as "LD (_DEBUF), DE", the load instruction saves the information in the DE register of the main CPU 63 to the DE buffer set in the work area 223 for non-specific control (step SM904). Further, as "LD (_HLBUF), HL", the load instruction saves the information in the HL register of the main CPU 63 to the HL buffer set in the work area 223 for non-specific control (step SM905). Further, as "LD (_IXBUF), IX", the load instruction saves the information in the IX register of the main CPU 63 to the IX buffer set in the work area 223 for non-specific control (step SM906). Further, as "LD (_IYBUF), IY", the load instruction saves the information of the IY register of the main CPU 63 to the IY buffer set in the work area 223 for non-specific control (step SM907).

By executing the processing of step SM902 to step SM907, the WA register, BC register, DE register, and HL register, which are some of the general-purpose registers, auxiliary registers, and index registers existing in the main CPU 63, are registered. , IX register and IY register information can be saved in the corresponding buffers in the work area 223 for non-specific control. The WA register, BC register, DE register, HL register, IX register, and IY register are registers used in the total division processing (step SM908) corresponding to the non-specific control. By saving the information set in such registers in the work area 223 for non-specific control before executing the total division processing (step SM908), the information of these registers used in the specific control is divided. It becomes possible to save before the processing (step SM908) is started. Therefore, even if these registers are overwritten during execution of the total division processing (step SM908), when the total division processing (step SM908) ends, the information saved in the work area 223 for non-specific control is stored in these registers. It is possible to return the state of these registers to the state corresponding to the specific control before the aggregation/division processing (step SM908) is executed by returning to the state of FIG.

Further, instead of saving all information of various general-purpose registers, auxiliary registers, and index registers in the work area 223 for non-specific control, a total division process (step SM908) corresponding to the non-specific control is performed. In the work area 223 for non-specific control, the information of the WA register, BC register, DE register, HL register, IX register, and IY register to be used is selectively saved in the work area 223 for non-specific control. It is possible to reduce the capacity secured for saving the register information. Therefore, it is possible to save the information in the register as described above while securing a large capacity of the work area 223 for non-specific control that can be used in the total division processing (step SM908). As a matter of course, various general-purpose registers, auxiliary registers, and index registers in the main CPU 63 other than the WA register, the BC register, the DE register, the HL register, the IX register, and the IY register are added to the total division process (step The information set before the start of SM908) is stored and held until the aggregation/division processing (step SM908) ends and the processing corresponding to the specific control is restarted.

Further, the register information is not saved in the non-specific control stack area 224 but is saved in the non-specific control work area 223, so that the capacity of the non-specific control stack area 224 can be reduced to that extent. It will be possible. Further, when the stack area 224 for non-specific control is used, the writing order of information is read first from the later information as described above. Therefore, the reading order of information is displaced due to some noise or the like. If this happens, all subsequent read order information will be restored to a different register. The probability of occurrence of such an event increases as the amount of information saved in the stack area 224 for non-specific control increases. On the other hand, by saving the information in the register in the work area 223 for non-specific control, it is possible to prevent the above event from occurring even when there is a large amount of information to be saved. ..

After executing the processing of steps SM902 to SM907, the total division processing (FIG. 349) is executed (step SM908). When executing the aggregate division process, the subroutine program corresponding to the aggregate division process set in the non-specific control program is executed, but when executing the subroutine program, the aggregate division process is executed. Information for specifying the return address of the later total division processing (FIG. 348) is written in the stack area 224 for non-specific control by the push command. When the total division processing is completed, the pop instruction reads the information for identifying the return address, and the program returns to the program of the total division execution processing (FIG. 348) indicated by the return address. Details of the total division processing (step SM908) will be described later.

After the total division processing is executed in step SM908, Y(r+γ) is set as the fixed address at the time of returning to the specific control to the stack pointer of the main CPU 63 by the load instruction as “LD SP,Y(r+γ)”. It is set (step SM909). The Y(r+γ) address is set as an address between Y(r+8) and Y(s) in the stack area 222 for specific control.

The amount of information stored in the stack area 222 for specific control is always constant immediately before the aggregation/division execution processing subroutine is executed in step SM806 of the residual processing (FIG. 347). The information of the stack pointer of the side CPU 63 (that is, the value of the stack pointer) is constant. In this case, as the information stored in the stack area 222 for specific control, for example, there is information on the return address of the residual processing (FIG. 347) after the aggregation/division execution processing (FIG. 348) is completed. The constant information of the stack pointer is Y(r+γ). Therefore, when the total division execution process (FIG. 348) that is the process corresponding to the non-specific control is ended and the process returns to the process corresponding to the specific control, Y(r+γ), which is the certain information, is transferred to the main CPU 63. It is possible to restore the information of the stack pointer to the information immediately before the start of the aggregation/division execution processing (FIG. 348) by setting the stack pointer of the above. By thus setting the fixed information in the stack pointer, the information of the stack pointer is restored to the information immediately before the aggregation/division execution process (FIG. 348) is started. It is not necessary to save the information of the stack pointer of the main CPU 63 corresponding to the specific control to the main RAM 65 before starting (348). Therefore, it is possible to reduce the processing load, and it is not necessary to secure an area for saving in the main RAM 65.

After that, the information saved in the WA buffer of the work area 223 for non-specific control is overwritten in the WA register of the main CPU 63 by the load instruction as "LD WA, (_WABUF)" (step SM910). Further, as "LD BC, (_BCBUF)", the information saved in the BC buffer of the work area 223 for non-specific control is overwritten in the BC register of the main CPU 63 by the load instruction (step SM911). Further, as "LD DE, (_DEBUF)", the information saved in the DE buffer of the work area 223 for non-specific control is overwritten in the DE register of the main CPU 63 by the load instruction (step SM912). Further, as "LD HL,(_HLBUF)", the information saved in the HL buffer of the work area 223 for non-specific control is overwritten in the HL register of the main CPU 63 by the load instruction (step SM913). Further, as "LD IX,(_IXBUF)", the information saved in the IX buffer of the work area 223 for non-specific control is overwritten in the IX register of the main CPU 63 by the load instruction (step SM914). Further, as "LDIY, (_IYBUF)", the information saved in the IY buffer of the work area 223 for non-specific control is overwritten in the IY register of the main CPU 63 by the load instruction (step SM915). By executing the processing of step SM910 to step SM915, the aggregation/division execution processing (FIG. 348) of each information of the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63 is started. It is possible to restore the information corresponding to the specific control immediately before being performed.

After that, the RETI instruction is executed as "RETI" (step SM916), and the totalization and division execution processing is ended. By executing the RETI instruction, the information of the flag register saved in the stack area 222 for specific control before execution of the aggregation/division execution process (FIG. 348) is returned to the flag register of the main CPU 63, and The state in which the generation of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) are prohibited is switched to the permitted state. As a result, the information in the flag register of the main CPU 63 is restored to the information for executing the specific control, and the first timer interrupt process and the second timer interrupt process can be newly executed.

Since the configuration is such that the RETI instruction is executed, the information of the flag register saved in the stack area 222 for specific control before the execution of the aggregation/division execution processing by one instruction (“RETI”) is used as the flag of the main CPU 63. The register can be restored, and the state in which the occurrence of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) is prohibited can be switched to the permitted state. Therefore, an instruction for returning the information of the flag register saved in the stack area 222 for specific control to the flag register of the main CPU 63 before the execution of the total division processing, and the first timer interrupt processing (FIG. 338) And the instruction for switching from the state in which the generation of the second timer interrupt process (FIG. 346) is prohibited to the state in which it is permitted is set in the program corresponding to the aggregation/division execution process, as compared with the case where the instruction is separately provided. The number of instructions can be reduced. As a result, the storage capacity of the main ROM 64 for storing the program corresponding to the total division processing can be reduced.

As described above, the execution of the RETI instruction permits the generation of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346). Therefore, if the RETI instruction is executed in the situation where the processing corresponding to the non-specific control remains, the first timer interrupt which is the processing corresponding to the specific control in the situation where the processing corresponding to the non-specific control is executed. The process (FIG. 338) or the second timer interrupt process (FIG. 346) is interrupted and activated. On the other hand, since the RETI instruction is executed in step SM916, which is the last step of the total division execution process (FIG. 348) that is the process corresponding to the non-specific control, the process corresponding to the non-specific control is performed. The CPU 63 of the main side prevents the first timer interrupt process (FIG. 338) or the second timer interrupt process (FIG. 346), which is a process corresponding to the specific control, from being interrupted and activated in the situation where is executed. In the state where the information in the flag register of 1 has been restored to the information for executing the specific control, the process can be returned to the residual process (FIG. 347) corresponding to the specific control.

Next, the total division processing executed by calling the program of the subroutine in step SM908 of the total division execution processing (FIG. 348) will be described. FIG. 349 is a flowchart showing the total division processing executed by the main CPU 63. The processes of steps SN101 to SN105 in the total division process are executed by the main CPU 63 using the non-specific control program and the non-specific control data.

As described above, in the check process (FIG. 341), the values of the various counters 231a to 231e of the normal counter area 231 in the work area 223 for non-specific control are updated in step SM204, and the result calculation process is executed in step SM205. Is executed. Then, the total payout number information is calculated in step SM304 of the result calculation process (FIG. 342), and the total number data is calculated in step SM306. Therefore, in the total division processing (FIG. 349), the total payout amount information calculated based on the current values of the various counters 231a to 231e in the normal counter area 231 is stored in the total payout amount area 632. The process starts in a state where the total number data calculated based on the current values of the various counters 231a to 231e in the normal counter area 231 is stored in the total number area 631.

In the total division processing, first, the total payout number of gaming balls in a situation that is neither the open/close execution mode or the high frequency support mode based on the jackpot result is grasped (step SN101). Specifically, the total payout amount information stored in the total payout amount area 632 in the work area 223 for non-specific control is grasped.

After that, the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) in a situation that is neither the open/close execution mode nor the high frequency support mode depending on the jackpot result is grasped ( Step SN102). Specifically, the total number data stored in the total number area 631 in the work area 223 for non-specific control is grasped.

After that, the base value division processing is executed (step SN103). In the base value division processing, the base value is calculated as a numerical value up to the fourth decimal place by dividing the total payout number of gaming balls grasped in step SN101 by the total number grasped in step SN102. Then, the base value rounding process is executed (step SN104). In the base value rounding process, first, the base value calculated in step SN103 is rounded off to the fourth decimal place to obtain the base value up to the third decimal place. After that, the base value is rounded off to the second decimal place by rounding off the third decimal place in the base value up to the third decimal place.

After that, the overwrite processing of the current area 311 is executed (step SN105), and the main tabulation division processing is ended. In the overwrite processing of the current area 311, the current area 311 is overwritten with the base value up to the second decimal place calculated in step SN103 and rounded off in step SN104. As a result, the latest base value stored in the current area 311 is updated.

As described above, when the total division process (FIG. 349) is started, the total payout amount information stored in the total payout amount area 632 and the total number data stored in the total number area 631 are used to perform the base value division process ( This is a configuration for executing step SN103). This makes it possible to omit the process of calculating the total payout amount information and the total amount data based on the values of the various counters 231a to 231e in the normal counter area 231 in the total division process. Therefore, the processing load for calculating the base value in the main CPU 63 can be reduced.

The processing of step SM513 in the already-described display processing (FIG. 344) is executed every time the display processing (FIG. 344) is executed regardless of the switching timing of the base value to be notified. As described above, the latest base value stored in the current area 311 is updated in step SN105 of the aggregation/division processing (FIG. 349). In this case, as described above, the process of step SM513 for setting the calculation result data in the display target setting area 276 is the display process (FIG. 344) regardless of the switching timing of the base value of the notification target. When the base value is changed in the situation where the base value of the current area 311 is the notification target by being executed every time, without waiting until the timing of switching the base value of the notification target, It is possible to notify the changed base value.

When the number of digits of the base value calculated by the base value division processing (step SN103) is large, the execution period of the base value fractional processing (step SN104) in which the base value is used as numerical information up to the second decimal place is extended. I will end up. If the base value is configured to be calculated in the first timer interrupt process (FIG. 338), the base value is calculated by the trade-off between the first timer interrupt period (specifically, 4 milliseconds) and the execution period of the base value fraction process. The number of digits of the base value that can be calculated by the division process will decrease. In the present embodiment, since the base value is calculated in the residual process (FIG. 347), it is possible to increase the number of digits of the base value calculated in the base value division process and store it in the current area 311. It is possible to improve the accuracy of the base value that is set. This makes it possible to grasp the presence or absence of an abnormality in the base value based on the accurate base value.

Returning to the description of the residual processing (FIG. 347), after performing the aggregation/division execution processing (FIG. 348) in step SM806, the first timer interrupt processing (FIG. 338) and the second timer are executed by the EI instruction as “EI”. Settings are made to switch from the state in which the occurrence of interrupt processing (FIG. 346) is prohibited to the state in which it is permitted (step SM807).

After that, as "JR RS_L", the address is jumped to the address of "RS_L" by the JR instruction (step SM808). As described above, “RS_L” is the address where the program corresponding to the residual process is stored in the main ROM 64 (FIG. 67). Therefore, the process returns to step SM801. Thus, the residual process (FIG. 347) is a loop process in which the processes of steps SM801 to SM808 are repeatedly executed.

As described above, in the residual processing (FIG. 347), after activation of the first timer interrupt processing (FIG. 338) and the second timer interrupt processing (FIG. 346) is prohibited in step SM801, the first timer interrupt processing and The processes of steps SM802 to SM806 are executed in a state where the activation of the second timer interrupt process is prohibited. After the processing of step SM806 is completed, the interrupts of the first timer interrupt processing and the second timer interrupt processing are permitted before returning to step SM801. With the configuration in which the processes of steps SM802 to SM806 are executed in a state where the first timer interrupt process and the second timer interrupt process are prohibited, the first process is executed in the situation where the processes of steps SM802 to SM806 are executed. It is possible to prevent the timer interrupt process or the second timer interrupt process from being interrupted and activated.

In the residual processing (FIG. 347), in the processing of steps SM802 to SM806 that are performed in a state in which the activation of the first timer interrupt processing and the second timer interrupt processing is prohibited, step M802 to step M802, which is processing corresponding to the specific control, is performed first. After the process of step SM805 is executed, a total division execution process (FIG. 348) which is a process corresponding to the non-specific control is executed in step SM806. When the RETI instruction is executed at the end of the aggregation/division execution process (FIG. 348), the flag register information saved in the stack area 222 for specific control before the aggregation/division execution process (FIG. 348) is mainly executed. While returning to the flag register of the side CPU 63, the state in which the generation of the first timer interrupt processing (FIG. 338) and the generation of the second timer interrupt processing (FIG. 346) are prohibited is switched to the permitted state. Therefore, if the aggregation/division execution process (FIG. 348) is executed in the middle of steps SM802 to SM806 in the residual process (FIG. 347), the RETI instruction is executed at the end of the aggregation/division execution process (FIG. 348). After that, it becomes necessary to perform a process of inhibiting the generation of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) before executing the remaining processes in steps SM802 to SM806. On the other hand, since the aggregation/division execution process (FIG. 348) is executed at the end (step SM806) of steps SM802 to SM806 in the residual process (FIG. 347), the aggregation/division execution process (FIG. 348) is executed. ), the process of prohibiting the occurrence of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) can be eliminated. Further, in the residual process (FIG. 347), it is possible to continuously execute the processes of steps SM802 to SM805, which are processes corresponding to the specific control.

By enabling the interrupts of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) in step SM807 of the residual process (FIG. 347), the first interrupt cycle (specifically, 4 mm). Second timer interrupt processing can be started when the second second interrupt cycle (specifically, 2 milliseconds) has elapsed, and the second timer interrupt processing can be started. Can be activated. As described above, the second timer interrupt process is preferentially activated when both the first interrupt period and the second interrupt period have elapsed.

According to this embodiment described in detail above, the following excellent effects are exhibited.

When the reset button 68c is pressed while the most recent base value is displayed on the first to fourth notification display devices 201 to 204, the first to fourth notification display devices 201 to 201 At 204, total number information is displayed. In the display of the total number information, the upper 4 digits of the total number data are displayed. The manager of the game hall grasps the degree of convergence about the latest base value stored in the current area 311 based on the total number information displayed on the first to fourth notification display devices 201 to 204. be able to.

The total number data grasped based on the total number information (upper 4 digits of the total number data) displayed on the first to fourth notification display devices 201 to 204 is the final total in the calculation period of the base value. If it is smaller than the number data (specifically, 60000), it can be understood that the degree of convergence of the latest base value is low. In addition, when the total number data grasped based on the total number information is close to the final total number data (specifically, 60000) in the base value calculation period, convergence of the latest base value is not detected. You can understand that the degree is high.

If the most recent base value is outside the theoretical range of base values, and if the degree of convergence of the most recent base value is low, the final base value in the current calculation period is the theoretical range of base values. You can figure out that it may fit in. Further, if the degree of convergence of the latest base value is high, it can be understood that the final base value in the current calculation period is likely to be out of the theoretical value range of the base value.

As the total number information, since it is configured to display the upper 4 digits of the total number data, which is any numerical information of "0" to "65535", the whole of the total number data (5-digit number) can be displayed. It is possible to grasp the degree of convergence of the latest base value while suppressing an increase in the number of the notification display devices 201 to 204 as compared with the configuration for displaying.

The display duration of the total number information (specifically 5 seconds) is grasped by using a switching timing counter for making it possible to grasp the display duration of the base value (concretely 5 seconds). As a result, as compared with a configuration in which a timing counter for grasping the display duration time of the total number information (specifically, 5 seconds) is provided separately from the switching timing counter, the display duration time of the total number information (specifically, Is 5 seconds), and the configuration for making it possible to grasp the time is simplified.

With the configuration in which the display of the base value and the display of the total number information are performed by the common first to fourth display devices 201 to 204, the monitoring burden on the manager of the game hall that monitors the base value. Can be reduced.

After the display of the total number information is finished, the most recent base value is displayed on the first to fourth notification display devices 201 to 204. Accordingly, after grasping the degree of convergence of the latest base value based on the display of the total number information, the latest base value can be confirmed again. The display of the latest base value that starts after the display of the total number information is continued for 5 seconds regardless of the period when the latest base value was displayed before the display of the total number information was started. Done. Therefore, even if the pressing of the reset button 68c is started immediately before the display of the most recent base value is started and the display of the total number information is started, the latest displayed after the display of the total number information is ended. It can be prevented that the display period of the base value of is extremely short.

Since the base value calculation period was newly started, the total number of game balls discharged from the game area PA (that is, supplied to the game area PA in a situation where neither the open/close execution mode due to the jackpot result nor the high-frequency support mode is used). If the total number of game balls does not reach the initial reference number (specifically 6000), the first to fourth notification display devices 201 to 204 display the calculation initial display in the display of the most recent base value. Be seen. When the operation initial display is being performed, the manager of the game hall does not have to operate the reset button 68c, and the latest base displayed on the first to fourth notification display devices 201 to 204 is displayed. It can be understood that the degree of convergence about the value is low. When the total number data does not reach the initial reference number (specifically 6000), the base value is highly likely to be out of the theoretical value range of the base value. By making it possible to easily understand that the total quantity data has not reached the initial reference quantity (specifically, 6000 pieces), it is possible to reduce the frequency of situations in which the display of total quantity information must be confirmed. You can As a result, the burden of monitoring the base value by the game hall manager can be reduced.

When the process corresponding to the non-specific control (test firing test execution process (FIG. 339), management execution process (FIG. 340), or total division execution process (FIG. 348)) is executed by the CALLI instruction, the flag register of the main CPU 63 Information is saved in the stack area 222 for specific control, and the interrupts of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) are prohibited. Then, it corresponds to the process (testing shot test execution process (FIG. 339), management execution process (FIG. 340), or total division execution process (FIG. 348) corresponding to the non-specific control set in the non-specific control program. The subroutine program is executed. By saving the information in the flag register before the program of the process corresponding to the non-specific control is started, it changes after the call of the process corresponding to the non-specific control or the start of the process corresponding to the non-specific control. It is possible to save the information in the flag register in the previous state in the stack area 222 for specific control. Further, by prohibiting the interrupt of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) before the program of the process corresponding to the non-specific control is started, the non-specific control is dealt with. It is possible to prevent the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346), which are processes corresponding to the specific control, from being interrupted and activated during execution of the process.

The configuration in which the trial shooting test execution process (FIG. 339) is executed by the CALLI instruction allows the information of the flag register of the main CPU 63 before the trial shooting test execution process (FIG. 339) is executed by one instruction (“CALLI”). Is saved in the stack area 222 for specific control, the interrupts of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) are prohibited, and the program of the test firing test execution process (FIG. 339) is executed. It can be started. Therefore, the instruction for saving the information in the flag register of the main CPU 63 to the stack area 222 for specific control and the interruption of the first timer interrupt processing (FIG. 338) and the second timer interrupt processing (FIG. 346) are prohibited. In order to execute the trial shooting test execution process (FIG. 339), as compared with the case where a command for executing the trial shooting test execution process (FIG. 339) and a command for executing the process of starting the program are separately provided. The number of instructions set in the program corresponding to the first timer interrupt process (FIG. 338) can be reduced. As a result, the storage capacity in the main ROM 64 for storing the program corresponding to the first timer interrupt processing (FIG. 338) can be reduced.

With the configuration in which the management execution process (FIG. 340) is executed by the CALLI instruction, the information of the flag register of the main CPU 63 is specified before the execution of the management execution process (FIG. 340) by one command (“CALLI”). Saving in the control stack area 222, prohibiting the interrupts of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346), and starting the program of the management execution process (FIG. 340). You can Therefore, the instruction for saving the information in the flag register of the main CPU 63 to the stack area 222 for specific control and the interruption of the first timer interrupt processing (FIG. 338) and the second timer interrupt processing (FIG. 346) are prohibited. To execute the management execution process (FIG. 340), as compared with the case where the command for executing the management execution process (FIG. 340) and the command for executing the process for starting the program are separately provided. The number of instructions set in the program corresponding to the timer interrupt processing (FIG. 338) can be reduced. As a result, the storage capacity in the main ROM 64 for storing the program corresponding to the first timer interrupt processing (FIG. 338) can be reduced.

By the configuration in which the aggregate division execution process (FIG. 348) is executed by the CALLI instruction, the information of the flag register of the main CPU 63 is executed before the aggregate division execution process (FIG. 348) is executed by one instruction (“CALLI”). Are saved in the stack area 222 for specific control, the interrupts of the first timer interrupt processing (FIG. 338) and the second timer interrupt processing (FIG. 346) are prohibited, and the program of the total division execution processing (FIG. 348) is executed. It can be started. Therefore, the instruction for saving the information in the flag register of the main CPU 63 to the stack area 222 for specific control and the interruption of the first timer interrupt processing (FIG. 338) and the second timer interrupt processing (FIG. 346) are prohibited. In order to execute the aggregate division execution process (FIG. 348), as compared with the case where the instruction for executing the aggregate division execution process (FIG. 348) and the command for executing the process for starting the program are separately provided. The number of instructions set in the program corresponding to the residual processing (FIG. 347) can be reduced. As a result, the storage capacity of the main ROM 64 for storing the program corresponding to the residual processing (FIG. 347) can be reduced.

The main CPU 63 terminates the process corresponding to the non-specific control (testing test execution process (FIG. 339), management execution process (FIG. 340), or total division execution process (FIG. 348)) and also corresponds to the specific control. Executes the RETI instruction. By executing the RETI instruction, the information of the flag register saved in the stack area 222 for specific control before the execution of the process corresponding to the non-specific control is returned to the flag register of the main CPU 63, and The state in which the generation of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) are prohibited is switched to the permitted state. As a result, the information in the flag register of the main CPU 63 is restored to the information for executing the specific control, and the first timer interrupt process and the second timer interrupt process can be newly executed.

When the process corresponding to the non-specific control (test firing test execution process (FIG. 339), management execution process (FIG. 340), or total division execution process (FIG. 348)) ends and the process corresponding to the specific control starts With the configuration for executing the RETI instruction, the information of the flag register saved in the stack area 222 for specific control before the execution of the process corresponding to the non-specific control is executed by one instruction (“RETI”). The flag register of the main CPU 63 can be restored, and the state in which the generation of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) is prohibited can be switched to the permitted state. .. Therefore, an instruction for restoring the flag register information saved in the stack area 222 for specific control to the flag register of the main CPU 63 before the execution of the process corresponding to the non-specific control, and the first timer interrupt process ( 338) and the instruction for switching the generation of the second timer interrupt processing (FIG. 346) from the prohibited state to the permitted state are separately provided, as compared with the case of the program of the processing corresponding to the non-specific control. The number of instructions set to can be reduced. As a result, the storage capacity of the main ROM 64 for storing the processing program corresponding to the non-specific control can be reduced.

The management execution process (step SL821) is executed in the first timer interrupt process (FIG. 338), and the total division execution process (step SM806) is executed in the residual process (FIG. 347). When the number of digits of the base value calculated in the base value division processing (step SN103) in the total division processing (FIG. 349) is large, the base value fraction processing for making the base value numerical information up to the second decimal point (step) The execution period of SN104) will be extended. If the base value is configured to be calculated in the first timer interrupt process (FIG. 338), the base value is calculated by the trade-off between the first timer interrupt period (specifically, 4 milliseconds) and the execution period of the base value fraction process. The number of digits of the base value that can be calculated by the division process will decrease. On the other hand, since the base value is calculated in the residual process (FIG. 347), the number of digits of the base value calculated in the base value division process (step SN103) can be increased and The accuracy of the base value stored in the area 311 can be improved. This makes it possible to grasp the presence or absence of an abnormality in the base value based on the accurate base value.

The first timer interrupt process (FIG. 338) includes a test shooting test execution process and a management execution process as processes corresponding to the non-specific control, and these processes are distributed and set in the first timer interrupt process. There is. In the first timer interrupt process, a process for advancing a game is executed as a process corresponding to the specific control. With the configuration in which the process corresponding to the non-specific control is set dispersedly in the first timer interrupt process, it is possible to prevent the situation where the process for advancing the game is not executed from continuing for a long time. .. Further, in the situation where the process corresponding to the specific control is being executed in the first timer interrupt process (FIG. 338), the second timer interrupt process (FIG. 346) should be interrupted and activated for the first timer interrupt process. You can On the other hand, when the process corresponding to the non-specific control is executed in the first timer interrupt process, the activation of the first timer interrupt process and the second timer interrupt process is prohibited at the start of the process corresponding to the non-specific control, The process corresponding to the non-specific control is executed in a state in which the activation of the first timer interrupt process and the second timer interrupt process is prohibited. For this reason, if the situation in which the processing corresponding to the non-specific control is being executed continues for a long time in the first timer interrupt processing, the situation in which the second timer interrupt processing cannot be activated will continue for a long time. On the other hand, since the process corresponding to the non-specific control is distributed and set in the first timer interrupt process, the second timer interrupt process ( It is possible to prevent the situation in which FIG. 346) cannot be started from continuing for a long time.

In the residual process (FIG. 347), after the activation of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) is prohibited in step SM801, the first timer interrupt process and the second timer interrupt process are performed. The processing of steps SM802 to SM806 is executed in a state where the activation of the processing is prohibited. After the processing of step SM806 is completed, the interrupts of the first timer interrupt processing and the second timer interrupt processing are permitted before returning to step SM801. With the configuration in which the processes of steps SM802 to SM806 are executed in a state where the first timer interrupt process and the second timer interrupt process are prohibited, the first process is executed in the situation where the processes of steps SM802 to SM806 are executed. It is possible to prevent the timer interrupt process or the second timer interrupt process from being interrupted and activated.

In the residual processing (FIG. 347), in the processing of steps SM802 to SM806 that are performed in a state in which the activation of the first timer interrupt processing and the second timer interrupt processing is prohibited, step M802 to step M802, which is processing corresponding to the specific control, is performed first. After the process of step SM805 is executed, a total division execution process (FIG. 348) which is a process corresponding to the non-specific control is executed in step SM806. When the RETI instruction is executed at the end of the aggregation/division execution process (FIG. 348), the flag register information saved in the stack area 222 for specific control before the aggregation/division execution process (FIG. 348) is mainly executed. While returning to the flag register of the side CPU 63, the state in which the generation of the first timer interrupt processing (FIG. 338) and the generation of the second timer interrupt processing (FIG. 346) are prohibited is switched to the permitted state. Therefore, if the aggregation/division execution process (FIG. 348) is executed in the middle of steps SM802 to SM806 in the residual process (FIG. 347), the RETI instruction is executed at the end of the aggregation/division execution process (FIG. 348). After that, it becomes necessary to perform a process of inhibiting the generation of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) before executing the remaining processes in steps SM802 to SM806. On the other hand, since the aggregation/division execution process (FIG. 348) is executed at the end (step SM806) of steps SM802 to SM806 in the residual process (FIG. 347), the aggregation/division execution process (FIG. 348) is executed. ), the process of prohibiting the occurrence of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) can be eliminated. Further, in the residual process (FIG. 347), it is possible to continuously execute the processes of steps SM802 to SM805, which are processes corresponding to the specific control.

In step SM806 of the residual process (FIG. 347), after performing the aggregate division execution process by the CALLI command, the process of step SM807 of the residual process (FIG. 347) in the 93rd embodiment is omitted, and Similar to step SM808 of the residual process (FIG. 347) in the 93rd embodiment, the configuration may be such that “JR RS_L” is returned to step SM801. As already described in the 93rd Embodiment, the RETI instruction is executed in step SM916 which is the final step of the total division processing (FIG. 348). Then, when the RETI instruction is executed, the information of the flag register saved in the stack area 222 for specific control before execution of the aggregation/division execution process (FIG. 348) is restored to the flag register of the main CPU 63. At the same time, the state in which the generation of the first timer interrupt processing (FIG. 338) and the generation of the second timer interrupt processing (FIG. 346) are prohibited is switched to the permitted state. As a result, it becomes possible to newly execute the first timer interrupt process and the second timer interrupt process. As described above, in the residual process (FIG. 347), the configuration is such that the aggregate division execution process is executed by the CALLI instruction in the step immediately before the step to be “JR RS_L”, and thus the step to be “JR RS_L” is performed. The generation of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) can be permitted without separately providing an EI instruction in the immediately preceding step. As a result, the number of instructions set in the program corresponding to the residual process (FIG. 347) can be reduced, and the storage capacity in the main side ROM 64 for storing the program corresponding to the residual process (FIG. 347) can be reduced. It can be reduced.

Also, the types of base values displayed on the first to fourth notification display devices 201 to 204 after the display of the total number information is limited to the most recent base value stored in the current area 311. There is no. After the display of the total number information is completed, the base value stored in the first history area 312, the base value stored in the second history area 313, and the first to fourth notification display devices 201 to 204 are displayed. Any of the base values stored in the 3 history area 314 may be displayed.

In addition, when the operation of the reset button 68c is performed in a situation where neither the setting value is being confirmed nor the setting value is being updated, at the timing when the operation is performed. As a configuration in which the display of the total number information is started on the first to fourth notification display devices 201 to 204 regardless of the type of the base value displayed on the first to fourth notification display devices 201 to 204 Good. Accordingly, when the display of the latest base value is completed on the first to fourth notification display devices 201 to 204, the total number information is displayed without waiting until the display of the latest base value is started next. Can be started.

Further, when returning from the process corresponding to the non-specific control (test firing test execution process (FIG. 339), management execution process (FIG. 340), or total division execution process (FIG. 348)) to the process corresponding to the specific control, RETI Instead of executing instructions, a pop instruction and an EI instruction may be executed. Specifically, in the trial shooting test execution process (FIG. 339), after the process of step SL915 is finished, first, as a “POP PSW”, a pop command is used to perform the specific control before the trial shooting test execution process (FIG. 339) is started. The information of the flag register saved in the stack area 222 is restored to the flag register of the main CPU 63. As a result, the information in the flag register of the main CPU 63 is restored to the information before the start of the test shot test execution process (FIG. 339). After that, the EI instruction is executed as “EI”. When the EI instruction is executed, the setting for switching from the state of prohibiting the generation of the first timer interrupt process (FIG. 338) and the generation of the second timer interrupt process (FIG. 346) to the permitted state is performed. This enables new execution of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346). Further, in the management execution process (FIG. 340), after the process of step SM115 is completed, first, as a “POP PSW”, a pop command is issued to the stack area 222 for specific control before the start of the management execution process (FIG. 340). The saved information of the flag register is restored to the flag register of the main CPU 63. As a result, the information in the flag register of the main CPU 63 is restored to the information before the start of the management execution process (FIG. 340). After that, the EI instruction is executed as “EI”. When the EI instruction is executed, the setting for switching from the state of prohibiting the generation of the first timer interrupt process (FIG. 338) and the generation of the second timer interrupt process (FIG. 346) to the permitted state is performed. This enables new execution of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346). Furthermore, in the total division execution process (FIG. 348), after the process of step SM915 is completed, first, as a “POP PSW”, by the pop command, the stack for specific control is executed before the total division execution process (FIG. 348) is started. The information of the flag register saved in the area 222 is returned to the flag register of the main CPU 63. As a result, the information in the flag register of the main CPU 63 is restored to the information before the start of the aggregation/division execution processing (FIG. 348). After that, the EI instruction is executed as “EI”. When the EI instruction is executed, the setting for switching from the state of prohibiting the generation of the first timer interrupt process (FIG. 338) and the generation of the second timer interrupt process (FIG. 346) to the permitted state is performed. This enables new execution of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346). As described above, even when the pop instruction and the EI instruction are executed when returning from the process corresponding to the non-specific control to the process corresponding to the specific control, the specific control is performed before the process corresponding to the non-specific control is started. The information of the flag register saved in the stack area 222 for data can be restored to the flag register of the main CPU 63, and the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) are generated. Settings can be made to switch from the prohibited state to the permitted state.

In addition, the RETI command is executed at the last step of the processing (testing shot execution processing (FIG. 339), management execution processing (FIG. 340), and total division execution processing (FIG. 348) corresponding to non-specific control. Alternatively, the RETI instruction may be executed after the processing corresponding to the non-specific control is completed. Specifically, in step SL807 of the first timer interrupt process (FIG. 338), after performing the processes of steps SL901 to SL915 of the test shot test execution process (FIG. 339), the first timer interrupt process (FIG. 338) is executed. Returning to step SL808, the RETI instruction is executed before the port output processing is executed. As a result, the information of the flag register of the main CPU 63 saved before the start of the test shooting test execution process can be restored to the flag register, and new execution of the first timer interrupt process and the second timer interrupt process can be performed. It can be possible. Further, after executing the processes of steps SM101 to SM115 of the management execution process (FIG. 340) in step SL821 of the first timer interrupt process (FIG. 338), the process returns to the first timer interrupt process (FIG. 338) to return the RETI instruction. To execute. Thereby, the information of the flag register of the main CPU 63 saved before the start of the management execution process can be restored to the flag register, and the first timer interrupt process and the second timer interrupt process can be newly executed. Can be In addition, after performing the processing of steps SM901 to SM915 of the aggregation/division execution processing (FIG. 348) in step SM806 of the residual processing (FIG. 347), the processing returns to the residual processing (FIG. 347) and replaced with the EI instruction in step SM807. To execute the RETI instruction. As a result, the information of the flag register of the main CPU 63 saved before the start of the aggregation/division execution process can be restored to the flag register, and the first timer interrupt process and the second timer interrupt process can be newly executed. It can be possible.

<94th Embodiment>
In the present embodiment, the processing configuration for executing the test shooting test execution processing and the management execution processing is different from that in the 93rd embodiment. Hereinafter, a configuration different from that of the 93rd embodiment will be described. The description of the same configuration as that of the 93rd embodiment is basically omitted.

FIG. 350 is a flowchart showing the first timer interrupt processing executed by the main CPU 63 in this embodiment. As in the 93rd embodiment, the first timer interrupt process is regularly activated in the first interrupt period of 4 milliseconds. Further, the program corresponding to the first timer interrupt processing is set to the program for specific control.

In steps SN201 to SN205, the same processing as steps SL801 to SL805 of the first timer interrupt processing (FIG. 338) in the 93rd embodiment is executed by a call instruction (CALL instruction). Note that in steps SN201 to SN205, the same processing as steps SL801 to SL805 of the first timer interrupt processing (FIG. 338) may be executed by the CALLS instruction, as in the 93rd embodiment.

Thereafter, similar to step SL806 of the first timer interrupt process (FIG. 338) in the 93rd embodiment, "1" is set to the game stop flag or the in-progress process flag in the work area 221 for specific control. It is determined whether or not there is (step SN206). If an affirmative determination is made in step SN206, the first timer interrupt processing is ended without executing the processing of steps SN207 to SN225.

On the other hand, when a negative determination is made in step SN206, the process proceeds to step SN207. In steps SN207 to SN218, the same processing as steps SL809 to SL820 of the first timer interrupt processing (FIG. 338) in the 93rd embodiment described above is executed by a call instruction (CALL instruction). Note that in steps SN207 to SN218, the same processing as steps SL809 to SL820 of the first timer interrupt processing (FIG. 338) may be executed by the CALLS instruction, as in the 93rd embodiment.

After that, the information of the flag register of the main CPU 63 is saved in the stack area 222 for specific control by a push command as "PUSH PSW" (step SN219). As already described in the 93rd Embodiment, the flag register includes a carry flag, a zero flag, a P/V flag, a sine flag, a half carry flag, etc., depending on the execution result of an operation instruction, a rotate instruction, an input/output instruction, or the like. The information in the flag register will change. The test shot test execution process executed in step SN221 and the management execution process executed in step SN222 are processes corresponding to non-specific control. By saving the information of the flag register of the main CPU 63 before the programs of the processing (testing test execution processing (step SN221) and management execution processing (step SN222)) corresponding to the non-specific control are started, the non-specific It is possible to save the information of the flag register in the state before change after the start of the process corresponding to the control or the process corresponding to the non-specific control to the stack area 222 for the specific control.

After that, as "DI", the DI instruction prohibits the interrupts of the first timer interrupt process (FIG. 350) and the second timer interrupt process (FIG. 346) (step SN220). As a result, during execution of the test shot test execution process (step SN221) and the management execution process (step SN222), which are processes corresponding to non-specific control, the first timer interrupt process (FIG. 350) is a process corresponding to specific control. Also, it is possible to prevent the second timer interrupt process (FIG. 346) from being interrupted and activated.

After that, the test shooting test execution process is executed by the call command (CALL command) (step SN221). FIG. 351 is a flow chart showing a test shooting test process executed by the main CPU 63. Note that the processes of steps SN301 to SN308 in the trial shooting test execution process are executed in the main CPU 63 using the non-specific control program and the non-specific control data.

In Step SN301 to Step SN307, the same processing as Step SL901 to Step SL907 of the trial shooting test execution processing (FIG. 339) in the 93rd embodiment is executed. As a result, the WA register, the BC register, the DE register, the HL register, the IX register, and the IY register, which are some of the general-purpose registers, auxiliary registers, and index registers existing in the registers of the main CPU 63, are registered. The information can be saved in the corresponding buffer in the work area 223 for non-specific control.

After that, in step SN308, similar to step SL908 of the trial shot test execution processing (FIG. 339) in the 93rd embodiment, the trial shot test processing is executed by a call instruction (CALL instruction). In the test shooting test process, similar to the 93rd embodiment, the test shooting test information to be output to the test shooting test apparatus which is an external device is generated, and the test shooting test information area 633 in the work area 223 for non-specific control is generated. To store. After that, the present trial shooting test execution processing is ended as it is without executing the processing of steps SL909 to SL916 of the trial shooting test execution processing (FIG. 339) in the 93rd embodiment. In this embodiment, some of the registers (WA register, BC register, DE register) of the main CPU 63 saved in the corresponding buffers in the work area 223 for non-specific control before starting the test shooting test process (step SN308). Without returning each information of the HL register, the IX register, and the IY register), the process proceeds to the next process (specifically, the management execution process).

Returning to the explanation of the first timer interrupt processing (FIG. 350), after performing the test shooting test execution processing in step SN221, the management execution processing is executed by the call instruction (CALL instruction) (step SN222). In this way, the test shot test execution process (step SN221) and the management execution process (step SN222) corresponding to the non-specific control are continuously executed in the first timer interrupt process (FIG. 350) corresponding to the specific control.

FIG. 352 is a flowchart showing the management execution process executed by the main CPU 63. The processes of steps SN401 to SN408 in the management execution process are executed in the main CPU 63 using the non-specific control program and the non-specific control data.

In the management execution process of this embodiment, first, similarly to step SM108 of the management execution process (FIG. 340) of the 93rd embodiment, a check process is executed by a call command (CALL command) (step SN401). As described above, some registers (WA) of the main CPU 63 saved in the corresponding buffers in the work area 223 for non-specific control before the start of the test shooting test process (step SN308 of the test shooting test execution process (FIG. 351)). Each information (register, BC register, DE register, HL register, IX register, and IY register) remains saved in the corresponding buffer in the work area 223 for non-specific control. Therefore, in the management execution process of this embodiment, the check process is executed in step SN401 without executing the processes of steps SM101 to SM107 of the management execution process (FIG. 340) in the 93rd embodiment. As a result, each information of some registers (WA register, BC register, DE register, HL register, IX register, and IY register) of the main CPU 63 saved in the corresponding buffer in the work area 223 for non-specific control Is restored after execution of the test shooting test processing, and information of some registers (WA register, BC register, DE register, HL register, IX register, and IY register) of the main CPU 63 is checked before execution of check processing. The process of saving to the corresponding buffer in the work area 223 for specific control can be omitted. Therefore, the storage capacity in the main ROM 64 for storing the program can be reduced.

The contents of the check process executed in step SN401 are the same as the contents of the check process (FIG. 341) already described in the 93rd embodiment. After that, the same processing as step SM109 to step SM115 of the management execution processing (FIG. 340) in the 93rd embodiment is executed. As a result, the information of the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63 is restored to the information corresponding to the specific control immediately before the processing corresponding to the non-specific control is started. It is possible to Note that the management execution process (FIG. 352) of this embodiment does not execute the SM116 process of the management execution process (FIG. 340) of the 93rd embodiment.

Returning to the explanation of the first timer interrupt process (FIG. 350), after performing the management execution process at step SN222, the step before the execution of the test shot test execution process (step SN221) by the pop command as “POP PSW” The information of the flag register saved in the stack area 222 for specific control at SN219 is restored to the flag register of the main CPU 63 (step SN223). As a result, the information in the flag register of the main CPU 63 is restored to the information at the start of the process of step SN219. That is, the information in the flag register of the main CPU 63 is restored to the information for executing the specific control.

After that, the EI instruction is executed as "EI" (step SN224). When the EI instruction is executed, the setting for switching from the state of prohibiting the generation of the first timer interrupt process (FIG. 338) and the generation of the second timer interrupt process (FIG. 346) to the permitted state is performed. This enables new execution of the first timer interrupt process (FIG. 350) and the second timer interrupt process (FIG. 346).

After that, the port output processing is executed by the call instruction (CALL instruction) (step SN225), and the first timer interrupt processing is ended. In the port output process in step SN225, similar to the port output process (step SL808) of the first timer interrupt process (FIG. 338) in the 93rd embodiment, the step of the test shot test process (test shot test execution process (FIG. 351)) is performed. In SN308), the processing for outputting the test shot test information stored in the test shot test information area 633 in the work area 223 for non-specific control to the test shot test apparatus which is an external device is executed. As already described in the 93rd Embodiment, the test shot test information is output to the test shot test device via the relay board (not shown). When the test shot test device is not connected, the test shot test information generated in the test shot test process is cleared without being output. Further, in the port output processing in step SN224, similarly to the port output processing (step SL808) in the first timer interrupt processing (FIG. 338) in the 93rd embodiment, the output information is set in the previous first timer interrupt processing. Is being performed, a process for performing output corresponding to the output information to the various drive units 32b and 34b is executed. For example, when the information to switch the special electric prize winning device 32 to the open state is set, the output of the drive signal to the special electric drive unit 32b is started, and the information to switch to the closed state is set. Stops the output of the drive signal. Further, when the information for switching the universal electric accessory 34a of the second operation port 34 to the open state is set, the output of the drive signal to the drive unit 34b for the general electric power is started to switch to the closed state. When the information is set, the output of the drive signal is stopped.

According to this embodiment described in detail above, the following excellent effects are exhibited.

In the first timer interrupt process (FIG. 350) corresponding to the specific control, the test shot test execution process (step SN221) and the management execution process (step SN222), which are the processes corresponding to the non-specific control, are continuously performed. This is the configuration to be executed. As a result, in the first timer interrupt process (FIG. 350), the process corresponding to the specific control is switched to the process corresponding to the non-specific control, and the process corresponding to the non-specific control is returned to the process corresponding to the specific control. It is possible to reduce the number of times to 1. Therefore, the processing load on the main CPU 63 for executing the processing corresponding to the non-specific control can be reduced.

When switching from the process corresponding to the specific control to the process corresponding to the non-specific control, the push command saves the information in the flag register of the main CPU 63 to the stack area 222 for the specific control (process of step SN219). Is executed, and at the time of returning from the process corresponding to the non-specific control to the process corresponding to the specific control, the information of the flag register saved in the stack area 222 for the specific control by the pop instruction is written to the main CPU 63. The process of returning to the flag register (process of step SN223) is executed. In the first timer interrupt process (FIG. 350 ), the number of times of switching from the process corresponding to the specific control to the process corresponding to the non-specific control, and the return from the process corresponding to the non-specific control to the process corresponding to the specific control is set. By suppressing the number of times to one, the process of saving the information in the flag register of the main CPU 63 to the stack area 222 for specific control, and the information of the flag register saved in the stack area 222 for specific control to the flag of the main CPU 63 It is possible to reduce the processing load of the main CPU 63 by suppressing the number of executions of the processing for returning to the register.

The trial shooting test process is executed in the final step of the trial shooting test execution process (step SN221), and the check process is executed in the first step of the management execution process (step SN222). Therefore, the test shooting test process and the check process are continuously executed. As a result, the number of executions of the process of saving the information set in the WA register, BC register, DE register, HL register, IX register, and IY register to the work area 223 for non-specific control can be suppressed to one. .. Further, each information of the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63 is restored to the information corresponding to the specific control immediately before the processing corresponding to the non-specific control is started. The number of times the process is executed can be suppressed to one. As a result, the processing load on the main CPU 63 can be reduced.

The first timer interrupt process (FIG. 350) is replaced by the first timer interrupt process (FIG. 350) instead of the configuration in which the test shot test execution process is executed in step SN221 and the management execution process is executed in step SN222. The configuration may be such that the management execution process is executed in step SN221 and the test shot test execution process is executed in step SN222. Also in this configuration, in step SN219, the information in the flag register of the main CPU 63 is saved in the stack area 222 for specific control, and in step SN220, the first timer interrupt processing (FIG. 350) and the second timer interrupt processing ( After the interrupt of FIG. 346) is prohibited, the management execution process and the test shooting test execution process, which are the processes corresponding to the non-specific control, can be continuously executed. After that, the information in the flag register of the main CPU 63, which has been saved in the stack area 222 for specific control, is restored, and the interrupts of the first timer interrupt process and the second timer interrupt process are permitted. As a result, in the first timer interrupt process (FIG. 350), the process corresponding to the specific control is switched to the process corresponding to the non-specific control, and the process corresponding to the non-specific control is returned to the process corresponding to the specific control. It is possible to reduce the number of times to 1.

<95th Embodiment>
In the present embodiment, the processing configuration for executing the test shooting test execution processing and the management execution processing is different from that in the 94th embodiment. The configuration different from that of the 94th embodiment will be described below. Note that the description of the same configuration as the 94th embodiment is basically omitted.

FIG. 353 is a flowchart showing the first timer interrupt processing executed by the main CPU 63 in this embodiment. It should be noted that the first timer interrupt process is regularly activated at a 4 millisecond cycle which is the first interrupt cycle. Further, the program corresponding to the first timer interrupt processing is set to the program for specific control.

In steps SN501 to SN518, the same processing as step SN201 to step SN218 of the first timer interrupt processing (FIG. 350) in the 94th embodiment is executed by the CALLS instruction. In steps SN501 to SN518, as in the 94th embodiment, a call instruction (CALL instruction) is used to execute the steps SN201 to SN218 of the first timer interrupt process (FIG. 350) in the 94th embodiment. It may be configured to execute the same processing.

After that, the test firing test execution process and the management execution process are executed by the CALLI command (step SN519). Similar to the 94th embodiment, the test-firing test execution process and the management execution process are processes corresponding to non-specific control.

When the test shooting test execution process and the management execution process are executed by the CALLI instruction, the information in the flag register of the main CPU 63 is first saved in the stack area 222 for specific control. By saving the information of the flag register before the program of the process (testing test execution process and management execution process) corresponding to the non-specific control is started, the call of the process corresponding to the non-specific control or the non-specific control is performed. It is possible to save the information of the flag register in the state before the change after the start of the process corresponding to the control in the stack area 222 for the specific control.

When the test shot test execution process and the management execution process are executed by the CALLI instruction, the first timer interrupt process (FIG. 338) and the second timer interrupt process are performed after the flag register information is saved in the stack area 222 for specific control. The interrupt of (FIG. 346) is prohibited. As a result, the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 338) that are processes corresponding to the specific control are performed during execution of the test-shooting test execution process and the management execution process that are processes corresponding to the non-specific control. It is possible to prevent 346) from being interrupted and activated.

When the shooting test execution process and the management execution process are executed by the CALLI instruction, the information in the flag register is saved in the stack area 222 for specific control, and the first timer interrupt process (FIG. 338) and the second timer interrupt process are performed. After the interruption of (FIG. 346) is prohibited, the program corresponding to the trial shooting test execution process is started. The processing contents of the trial shooting test execution processing are as already described in the 94th embodiment. Then, the program corresponding to the management execution process (FIG. 354) is started. The details of the management execution process (FIG. 354) will be described later.

As described above, the configuration in which the test firing test execution process (FIG. 351) and the management execution process (FIG. 354) are executed by the CALLI command allows the information of the flag register of the main CPU 63 to be executed by one command (“CALLI”). Is saved in the stack area 222 for specific control, the interrupts of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) are prohibited, and the program corresponding to the test shot test execution process (FIG. 351) is executed. In addition, the program corresponding to the management execution process (FIG. 354) can be started after the end of the test shooting test execution process (FIG. 351). Therefore, the instruction for saving the information in the flag register of the main CPU 63 to the stack area 222 for specific control and the interruption of the first timer interrupt processing (FIG. 338) and the second timer interrupt processing (FIG. 346) are prohibited. Compared with the case where the instruction for starting, the instruction for starting the program of the trial shooting test execution process (FIG. 351), and the instruction for starting the program of the management execution process (FIG. 354) are individually provided, It is possible to reduce the number of instructions set in the program corresponding to the first timer interrupt process (FIG. 338) for executing the test shot test execution process (FIG. 351) and the management execution process (FIG. 354). As a result, the storage capacity in the main ROM 64 for storing the program corresponding to the first timer interrupt processing (FIG. 338) can be reduced.

FIG. 354 is a flowchart showing a management execution process executed by the main CPU 63. The processes of steps SN601 to SN609 in the management execution process are executed in the main CPU 63 using the non-specific control program and the non-specific control data.

In Step SN601 to Step SN608, the same processing as Step SN401 to Step SN408 of the management execution processing (FIG. 352) in the 94th embodiment is executed. After that, similarly to step SM116 of the management execution process (FIG. 340) in the 93rd embodiment, the RETI command is executed as “RETI” (step SN609), and this management execution process is ended. By executing the RETI instruction, the information of the flag register saved in the stack area 222 for specific control before the execution of the test shot test execution process (FIG. 351) is returned to the flag register of the main CPU 63, and The state in which the generation of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) are prohibited is switched to the permitted state. As a result, the information in the flag register of the main CPU 63 is restored to the information for executing the specific control, and the first timer interrupt process and the second timer interrupt process can be newly executed.

Since the configuration is such that the RETI instruction is executed, the information of the flag register saved in the stack area 222 for specific control before the execution of the test shot test execution processing (FIG. 351) is mainly executed by one instruction (“RETI”). The flag register of the side CPU 63 can be restored, and at the same time, the generation of the first timer interrupt process (FIG. 353) and the second timer interrupt process (FIG. 346) can be switched from the prohibited state to the permitted state. Therefore, an instruction for restoring the flag register information saved in the stack area 222 for specific control to the flag register of the main CPU 63 before the execution of the test shot test execution process (FIG. 351), and the first timer interrupt process (FIG. 353) and the instruction for switching from the state in which the generation of the second timer interrupt process (FIG. 346) is prohibited to the state in which the second timer interrupt process (FIG. 346) is individually provided are compared to the case where the management execution process (FIG. 354) is performed. The number of instructions set in the program of the corresponding process can be reduced. As a result, the storage capacity of the main ROM 64 for storing the program corresponding to the management execution process (FIG. 354) can be reduced.

As described above, the execution of the RETI instruction permits the generation of the first timer interrupt process (FIG. 353) and the second timer interrupt process (FIG. 346). Therefore, if the RETI instruction is executed in the situation where the processing corresponding to the non-specific control remains, the first timer interrupt which is the processing corresponding to the specific control in the situation where the processing corresponding to the non-specific control is executed. The process (FIG. 353) or the second timer interrupt process (FIG. 346) is interrupted and started. On the other hand, since the RETI command is executed in step SN609 which is the last step of the management execution process (FIG. 354) that is the process corresponding to the non-specific control, the process corresponding to the non-specific control is While preventing the first timer interrupt process (FIG. 353) or the second timer interrupt process (FIG. 346), which is a process corresponding to the specific control, from being interrupted and activated in the running state, the main CPU 63 When the information in the flag register has returned to the information for executing the specific control, it is possible to return to the first timer interrupt process (FIG. 353) which is the process corresponding to the specific control.

In the first timer interrupt processing (FIG. 353) corresponding to the specific control, the test shot test execution processing (FIG. 351) and the management execution processing (FIG. 354) corresponding to the non-specific control are continuously performed. This is the configuration to be executed. Therefore, the management execution process (FIG. 354) is executed without executing the RETI command at the end of the test firing test execution process (FIG. 351), and the RETI command is executed at the end of the management execution process. .. As a result, it is not necessary to set the RETI instruction in the program corresponding to the trial shooting test execution process (FIG. 351). Therefore, it is possible to reduce the storage capacity of the main ROM 64 for storing the program corresponding to the test shot test execution process (FIG. 351).

Returning to the explanation of the first timer interrupt process (FIG. 353), after executing the test shot test execution process (FIG. 351) and the management execution process (FIG. 354) in step SN519, a CALLS command is used to execute the process in the 94th embodiment. Similar to step SN225 of the first timer interrupt process (FIG. 350), the port output process is executed (step SN520), and the first timer interrupt process (FIG. 353) is ended. The processing contents of the port output processing are as already described in the 94th embodiment. Incidentally, in step SN520, the port output processing may be executed by a call instruction (CALL instruction) as in the 94th embodiment.

According to this embodiment described in detail above, the following excellent effects are exhibited.

The configuration in which the test firing test execution process (FIG. 351) and the management execution process (FIG. 354) are executed by the CALLI command allows the information of the flag register of the main CPU 63 to be used for specific control by one command (“CALLI”). Of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) are prohibited, and the program corresponding to the test firing test execution process (FIG. 351) is started. In addition, the program corresponding to the management execution process (FIG. 354) can be started after the end of the trial shooting test execution process (FIG. 351). Therefore, the instruction for saving the information in the flag register of the main CPU 63 to the stack area 222 for specific control and the interruption of the first timer interrupt processing (FIG. 338) and the second timer interrupt processing (FIG. 346) are prohibited. Compared with the case where the instruction for starting, the instruction for starting the program of the trial shooting test execution process (FIG. 351), and the instruction for starting the program of the management execution process (FIG. 354) are individually provided, It is possible to reduce the number of instructions set in the program corresponding to the first timer interrupt process (FIG. 338) for executing the test shot test execution process (FIG. 351) and the management execution process (FIG. 354). As a result, the storage capacity in the main ROM 64 for storing the program corresponding to the first timer interrupt processing (FIG. 338) can be reduced.

Since the RETI command is executed at step SN609 which is the last step of the management execution process (FIG. 354), one command (“RETI”) causes the RETI command to be executed before execution of the test shot test execution process (FIG. 351). The information of the flag register saved in the stack area 222 for specific control can be restored to the flag register of the main CPU 63, and the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) can be performed. It is possible to switch from the state in which the generation is prohibited to the state in which the generation is permitted. Therefore, an instruction for restoring the flag register information saved in the stack area 222 for specific control to the flag register of the main CPU 63 before the execution of the test shot test execution process (FIG. 351), and the first timer interrupt process (FIG. 338) and the instruction for switching the generation of the second timer interrupt processing (FIG. 346) from the prohibited state to the permitted state are separately provided, the management execution processing (FIG. 354) is performed. The number of instructions set in the program of the corresponding process can be reduced. As a result, the storage capacity of the main ROM 64 for storing the program corresponding to the management execution process (FIG. 354) can be reduced.

In the first timer interrupt processing (FIG. 353) corresponding to the specific control, the test shot test execution processing (FIG. 351) and the management execution processing (FIG. 354) corresponding to the non-specific control are continuously performed. This is the configuration to be executed. As a result, in the first timer interrupt process (FIG. 353), the process corresponding to the specific control is switched to the process corresponding to the non-specific control, and the process corresponding to the non-specific control is returned to the process corresponding to the specific control. It is possible to reduce the number of times to 1. Therefore, the processing load on the main CPU 63 for executing the processing corresponding to the non-specific control can be reduced. Since the test firing test execution process (FIG. 351) and the management execution process (FIG. 354) that are processes corresponding to the non-specific control are continuously executed, the RETI is executed at the end of the test firing test execution process (FIG. 351). The management execution process (FIG. 354) may be executed without executing the command, and the RETI command may be executed at the end of the management execution process. As a result, it is not necessary to set the RETI instruction in the program corresponding to the trial shooting test execution process (FIG. 351). Therefore, it is possible to reduce the storage capacity of the main ROM 64 for storing the program corresponding to the test shot test execution process (FIG. 351).

Note that, instead of the configuration in which the RETI instruction is executed in step SN609, which is the final step of the management execution process (FIG. 354), the configuration in which the pop instruction and the EI instruction are executed may be adopted. Specifically, in the management execution process (FIG. 354), after the process of step SN608 is completed, first, as a "POP PSW", a pop command is used to execute a specific control before the start of the test shot test execution process (FIG. 351). The information of the flag register saved in the stack area 222 is restored to the flag register of the main CPU 63. As a result, the information in the flag register of the main CPU 63 is restored to the information before the start of the test shot test execution process (FIG. 351). After that, the EI instruction is executed as “EI”. When the EI instruction is executed, the setting for switching from the state in which the generation of the first timer interrupt processing (FIG. 353) and the generation in the second timer interrupt processing (FIG. 346) are prohibited to the permitted state is performed. This enables new execution of the first timer interrupt process (FIG. 353) and the second timer interrupt process (FIG. 346). As described above, even if the pop instruction and the EI instruction are executed instead of the RETI instruction, the information of the flag register saved in the stack area 222 for specific control before the start of the management execution process (FIG. 354) is mainly stored. The flag register of the side CPU 63 can be restored, and the setting for switching from the state in which the generation of the first timer interrupt processing (FIG. 353) and the generation in the second timer interrupt processing (FIG. 346) is prohibited to the permitted state is set. It can be carried out.

Further, instead of executing the RETI command in the last step (step SN609) of the management executing process (FIG. 354), the RETI command may be executed after the management executing process is completed. Specifically, in step SN519 of the first timer interrupt process (FIG. 353), after performing the test shot test execution process (FIG. 351) and the management execution process (FIG. 354) of steps SN601 to SN608, the first Returning to the timer interrupt process (FIG. 353), the RETI instruction is executed before the port output process in step SN520. As a result, the information of the flag register of the main CPU 63 saved before the start of the test shooting test execution process can be restored to the flag register, and new execution of the first timer interrupt process and the second timer interrupt process can be performed. It can be possible.

Further, in step SN519 of the first timer interrupt processing (FIG. 353), the management execution processing and the test shooting test execution processing may be executed in the order of the management execution processing→the test shooting test execution processing by the CALLI command. Also in this configuration, the information in the flag register of the main CPU 63 is saved in the stack area 222 for specific control, and the interrupts of the first timer interrupt process (FIG. 353) and the second timer interrupt process (FIG. 346) are prohibited. After that, the management execution process and the test shooting test execution process, which are processes corresponding to the non-specific control, can be continuously executed. After that, the information in the flag register of the main CPU 63, which has been saved in the stack area 222 for specific control, is restored, and the interrupts of the first timer interrupt process and the second timer interrupt process are permitted. As a result, in the first timer interrupt process (FIG. 353), the process corresponding to the specific control is switched to the process corresponding to the non-specific control, and the process corresponding to the non-specific control is returned to the process corresponding to the specific control. It is possible to reduce the number of times to 1.

<96th Embodiment>
In this embodiment, the display mode of the information corresponding to the total number data is different from that in the 93rd embodiment. Hereinafter, a configuration different from that of the 93rd embodiment will be described. The description of the same configuration as that of the 93rd embodiment is basically omitted.

FIG. 355(a) is a front view of the game board 24 in the present embodiment. A special figure unit 641 is provided in place of the special figure unit 37 (FIG. 3) in the first embodiment in the lower right corner, which is an area where the game ball does not pass in the game area PA, and A universal figure unit 642 is provided in place of the universal figure unit 38 (FIG. 3) in the first embodiment.

The special drawing unit 641 is provided with a special drawing display portion 641a in which eight LEDs capable of emitting light are arranged in a horizontal row. The display area of the special figure display portion 641a is smaller than the display surface 41a of the symbol display device 41. In the special figure display portion 37a, a variation display or a predetermined display is performed by a winning lottery triggered by winning in the first operating port 33 or winning in the second operating port 34. Then, the result display corresponding to the lottery result is performed. These variable display, predetermined display, and result display are executed by controlling the light emission of eight LEDs in the special figure display unit 37a.

In the special figure unit 641, below the special figure display section 641a, a special figure hold display section 641b in which four LEDs capable of emitting light are arranged in a horizontal row is provided. The maximum number of game balls winning the first operating port 33 or the second operating port 34 is reserved up to 4, and the reserved number is displayed by turning on the LED of the special figure suspension display portion 641b.

The general drawing unit 642 is provided below the special drawing unit 641. The universal figure unit 642 is provided with a universal figure display section 642a in which eight LEDs capable of emitting light are arranged in a horizontal row. Similar to the first embodiment, the internal lottery is performed with the winning of the through gate 35 as a trigger, and the variable display is performed on the universal figure display portion 642a. Then, when the result of the internal lottery is the electric-power-opening winning, the stop result corresponding to the result is displayed, and the variable display of the general-purpose display unit 642a is ended, the general-use electric product 34a is opened in a predetermined manner. It shifts to the state that the state is open. The variable display is executed by controlling the light emission of the eight LEDs in the universal figure display unit 642a.

In the universal figure unit 642, below the universal figure display section 642a, a universal figure hold display section 642b in which four LEDs capable of emitting light are arranged in a horizontal row is provided. The maximum number of game balls winning the through gate 35 is four, and the number of the reserved balls is displayed by lighting the universal figure reservation display section 642b.

As already described in the 93rd embodiment, when the reset button 68c is pressed in the situation where the latest base values are displayed on the first to fourth notification display devices 201 to 204, the total number The total number information in which the upper four digits of the data are displayed on the first to fourth notification display devices 201 to 204 is displayed. As already described in the 93rd Embodiment, the total number data is 2-byte numerical value information indicating any numerical value of “0” to “65535”.

As already described in the 93rd Embodiment, in the situation where the setting value is being confirmed, the setting value is being confirmed on the first to fourth notification display devices 201 to 204. In addition to the display shown and the display showing the current setting value, in the situation where the setting value is being updated, in the situation where the setting value is being updated on the first to fourth notification display devices 201 to 204. A display indicating that there is and a display indicating the current set value are displayed. Therefore, in the situation where the setting value is being confirmed and the setting value is being updated, the total number information is not displayed on the first to fourth notification display devices 201 to 204.

In the present embodiment, in the situation where the setting value is being updated and the setting value is being confirmed, the eight LEDs of the special figure display portion 641a and the eight LEDs of the general figure display portion 642a are displayed. Is used to display the total number data indicating the total number data. This allows the manager of the game hall to keep track of the total number of pieces of data even when the setting value is being confirmed and the setting value is being updated, and the most recent base It is possible to grasp the degree of convergence of the values.

FIG. 355(b) is an explanatory diagram for explaining the states of the special figure display unit 641a and the general figure display unit 642a in the situation where the total number display is being performed. In the total number display performed using the special figure display unit 641a and the general figure display unit 642a, the special figure display is performed in a mode corresponding to the lower 8 bits (0th to 7th bits) of the total number data, which is 2-byte data. The light emission control of the eight LEDs in the unit 641a is performed, and the light emission control of the eight LEDs in the universal figure display unit 642a is performed in a manner corresponding to the upper 8 bits (8th bit to 15th bit) of the total number data. Is done.

The eight LEDs in the special figure display portion 641a have a one-to-one correspondence with the lower 8 bits (0th to 7th bits) of the total number data. Specifically, the nth LED (n is an integer of 1 to 8) from the right in the special figure display portion 641a corresponds to the (n-1)th bit in the total number data. Further, the eight LEDs in the universal figure display portion 642a have a one-to-one correspondence with the upper 8 bits (8th to 15th bits) of the total number data. Specifically, the m-th LED (m is an integer from 1 to 8) from the right in the universal figure display portion 642a corresponds to the (m+7)th bit in the total number data. In the total number display, when the value of the bit corresponding to the LED is “1”, the LED is turned on, and when the value of the bit corresponding to the LED is “0”, the LED is turned off. Thus, the light emission control of each LED in the special figure display portion 641a and the general figure display portion 642a is performed.

For example, when the total number data is “0111010100110000” in binary notation (“30000” in decimal number notation), the fourth bit, the fifth bit, the eighth bit, the tenth bit, and the twelfth to tenth bits of the total number data. Since the 14-bit value is “1”, as shown in FIG. 355(b), the fifth and sixth LEDs from the right in the special figure display unit 641a are turned on and the general figure display unit 642a is turned on. The 1st, 3rd and 5th to 7th LEDs from the right are turned on. Also, since the values of the 0th to 3rd bits, the 6th bit, the 7th bit, the 9th bit, the 11th bit, and the 15th bit of the total number data are “0”, they are shown in FIG. 355(b). As described above, in the special figure display portion 641a, the 1st to 4th, 7th and 8th LEDs from the right are turned off, and in the general figure display portion 642a the 2nd, 4th and 8th LEDs from the right are turned off. It becomes a state.

In this way, the entire 2-byte total number data is displayed in binary using the 16 LEDs in total in the special figure display portion 641a and the general figure display portion 642a. This makes it possible to grasp the entire total number data and also the degree of convergence of the latest base value.

Similar to the thirty-third embodiment, the main control board 61 is provided with a first display circuit 261 (FIG. 119) corresponding to the special figure display section 641a and corresponding to the special figure hold display section 641b. The second display circuit 262 (FIG. 119) is provided, and the third display circuit 263 (FIG. 119) is provided corresponding to the universal figure display portion 642a, and the universal figure hold display portion 642b is provided. A fourth display circuit 264 (FIG. 119) is provided, and a fifth display circuit 265 (FIG. 119) is provided corresponding to the first to fourth notification display devices 201 to 204. The main control board 61 is provided with one display IC 266 (FIG. 119) so as to be common to all of the first to fifth display circuits 261 to 265.

Similar to the thirty-third embodiment, the work area 221 for specific control includes a first display data buffer 271 (FIG. 120(a)) in which display data to be supplied to the first display circuit 261 is stored. , A second display data buffer 272 (FIG. 120A) in which display data to be supplied to the second display circuit 262 is stored, and a third display data buffer in which the display data to be supplied to the third display circuit 263 is stored. The display data buffer 273 (FIG. 120(a)), the fourth display data buffer 274 (FIG. 120(a)) in which the display data to be supplied to the fourth display circuit 264 is stored, and the fifth display circuit 265. A fifth display data buffer 275 (FIG. 120(a)) in which display data to be supplied is stored is provided.

Similar to the thirty-third embodiment, the first display data buffer 271 stores the display data for causing the special figure display unit 641a to perform a predetermined display, and transmits the display data to the first display circuit 261. When the number of times of the 2-timer interrupt process (FIG. 346) is reached, the display data stored in the first display data buffer 271 is transmitted to the display IC 266. The second display data buffer 272 stores the display data for causing the special figure reservation display unit 641b to perform a predetermined display, and the second timer interrupt process (FIG. 346) for transmitting the display data to the second display circuit 262 is performed. When it is the processing time, the display data stored in the second display data buffer 272 is transmitted to the display IC 266. The third display data buffer 273 stores the display data for causing the universal graphic display unit 642a to perform a predetermined display, and the process of the second timer interrupt process (FIG. 346) for transmitting the display data to the third display circuit 263. When the number of times is reached, the display data stored in the third display data buffer 273 is transmitted to the display IC 266. The fourth display data buffer 274 stores the display data for causing the universal figure reservation display unit 642b to perform a predetermined display, and the second timer interrupt process (FIG. 346) of the second timer interrupt process for transmitting the display data to the fourth display circuit 264 is performed. When it is the processing time, the display data stored in the fourth display data buffer 274 is transmitted to the display IC 266.

In the display control process (FIG. 356) described later, when the setting value is being updated or the setting value is being confirmed, the total number data stored in the total number area 631 The lower 8 bits are set as the display data in the first display data buffer 271, and the upper 8 bits of the total number data are set as the display data in the third display data buffer 273. As a result, the display control of the eight LEDs in the special figure display portion 641a is performed in a manner corresponding to the lower 8 bits of the total number data, and the general figure display portion 642a is controlled in a manner corresponding to the upper 8 bits of the total number data. The display control of the eight LEDs is performed.

In this way, the light emitting state of the LED corresponding to the bit is controlled based on the value of each bit of the total number data, which is 2-byte data, so that the total number data is directly stored in the special figure display unit 641a and the general display. It can be used as display data of the diagram display unit 642a. Since the process of generating display data for displaying the total number in the special figure display unit 641a and the general figure display unit 642a based on the total number data can be omitted, the special figure display unit 641a and the general figure display unit 642a can be omitted. It is possible to simplify the processing configuration for executing the total number display in and to reduce the processing load on the main CPU 63.

Next, the display control processing executed by the main CPU 63 will be described with reference to the flowchart in FIG. 356. The display control process is executed in step SL816 of the first timer interrupt process (FIG. 338). Further, the program corresponding to the display control process is set to the program for specific control.

In the display control process, first, it is determined whether or not "1" is set in the setting update display flag in the specific control work area 221 (step SN701). Similar to the 93rd embodiment, the setting update display flag is used by the main CPU 63 to specify whether or not the setting value update processing (FIG. 137) is being executed by the main CPU 63. It is a flag. The situation where the setting update display flag is set to "1" corresponds to the situation where the setting value updating process (Fig. 137) is being executed. When a negative determination is made in step SN701, it is determined whether or not "1" is set in the setting confirmation display flag in the work area 221 for specific control (step SN702). Similar to the 93rd embodiment described above, the setting confirmation display flag is used by the main CPU 63 to identify whether or not the main CPU 63 is executing the setting confirmation process (FIG. 136). It is a flag. The situation in which "1" is set in the setting confirmation display flag corresponds to the situation in which the setting confirmation process (Fig. 136) is being executed.

If neither the situation where the setting value update processing (FIG. 137) is being executed nor the situation where the setting confirmation processing (FIG. 136) is being executed (step SN701: NO, step SN702: NO), the first The setting process of the display data buffer 271 is executed (step SN703). In the setting process of the first display data buffer 271, the display data corresponding to the result of the special figure special power control process (step SL814) in the first timer interrupt process (FIG. 338) is stored in the first display data buffer 271. As a result, a predetermined display corresponding to the result of the special figure special power control processing is performed on the special figure display unit 641a.

After that, the setting process of the third display data buffer 273 is executed (step SN704). In the setting process of the third display data buffer 273, the display data corresponding to the result of the universal figure universal communication control process (step SL815) in the first timer interrupt process (FIG. 338) is stored in the third display data buffer 273. As a result, a predetermined display corresponding to the result of the universal graphic/universal communication control process is displayed on the universal graphic display unit 642a.

On the other hand, when the setting value update process (FIG. 137) is being performed (step SN701: YES), or the setting confirmation process (FIG. 136) is being performed (step SN702: YES). First, the total number data stored in the total number area 631 in the work area 223 for non-specific control is grasped (step SN705). As described above in the 93rd embodiment, the work area 223 for non-specific control cannot store information when the process corresponding to the specific control is executed by the main CPU 63. Reading is possible. Therefore, the total number data stored in the total number area 631 in the non-specific control work area 223 can be grasped in step SN705 executed by using the specific control program.

After that, the lower 8 bits of the total number data grasped in step SN705 are stored in the first display data buffer 271 as display data (step SN706). Thereby, the light emission control of the eight LEDs in the special figure display unit 641a is performed in a manner corresponding to the value of the lower 8 bits of the total number data (information of "0" or "1"). After that, the upper 8 bits of the total number data grasped in step SN705 are stored in the third display data buffer 273 as display data (step SN707). As a result, the light emission control of the eight LEDs in the general figure display portion 642a is performed in a manner corresponding to the value of the upper 8 bits of the total number data (information of "0" or "1").

When the process of step SN704 is executed or the process of step SN707 is executed, the setting process of the second display data buffer 272 is executed (step SN708). In the setting process of the second display data buffer 272, the display data corresponding to the result of the special figure special power control process (step SL814) in the first timer interrupt process (FIG. 338) is stored in the second display data buffer 272. As a result, a predetermined display corresponding to the result of the special figure special power control processing is performed on the special figure pending display unit 641b.

After that, the setting process of the fourth display data buffer 274 is executed (step SN709). In the setting process of the fourth display data buffer 274, the display data corresponding to the result of the universal figure universal communication control process (step SL815) in the first timer interrupt process (FIG. 338) is stored in the fourth display data buffer 274. As a result, a predetermined display corresponding to the result of the general/universal/universal electric power control processing is displayed on the general/universal/universal language reservation display unit 642b.

After that, the setting process of the fifth display data buffer 275 is executed (step SN710), and this display control process is ended. In the setting process of the fifth display data buffer 275, the display data set in the display target setting area 276 of the work area 223 for non-specific control is grasped, and the grasped display data is stored in the fifth display data buffer 275. To do. Thus, if the setting value is being confirmed, a display indicating that the setting value is being confirmed on the first to fourth notification display devices 201 to 204 and a display showing the current setting value Is performed, and if the setting value is being updated, a display indicating that the setting value is being updated on the first to fourth notification display devices 201 to 204 and the current setting value are displayed. The display shown is made. If neither the situation of confirming the set value nor the situation of updating the set value, the base value in the current area 311, the base value in the first history area 312, the base value in the second history area 313 are displayed. Of the values, the base value in the third history area 314, and the total number information, the display corresponding to the information that is the notification target is performed on the first to fourth notification display devices 201 to 204. As described above, in the work area 223 for non-specific control, when the process corresponding to the specific control is executed by the main CPU 63, the information cannot be stored, but the information can be read. Therefore, it is possible to grasp the display data stored in the display target setting area 276 of the non-specific control work area 223 in step SN710 executed by using the specific control program.

According to this embodiment described in detail above, the following excellent effects are exhibited.

The total number display showing the total number data is performed by using the eight LEDs of the special figure display portion 641a and the eight LEDs of the general figure display portion 642a. As a result, it is possible to grasp the information of the total number data based on the total number display performed on the special figure display unit 641a and the general figure display unit 642a, and to determine the degree of convergence of the latest base value. Can be grasped. The manager of the game hall finds that the total number data is smaller than the shift reference number (specifically 60,000) based on the total number display performed on the special figure display unit 641a and the general figure display unit 642a. When grasped, it can be understood that the degree of convergence of the latest base value is low, and the total number data is shifted based on the total number display performed on the special figure display unit 641a and the general figure display unit 642a. When it is grasped that the number is close to the reference number (specifically, 60000), it can be grasped that the degree of convergence of the latest base value is high.

According to the configuration, the light emitting state of the LED corresponding to the bit is controlled based on the value of each bit of the total number data which is 2-byte data. Therefore, the total number data can be directly used as the display data of the special figure display unit 641a and the general figure display unit 642a. Since the process of generating display data for displaying the total number in the special figure display unit 641a and the general figure display unit 642a based on the total number data can be omitted, the special figure display unit 641a and the general figure display unit 642a can be omitted. It is possible to simplify the processing configuration for executing the total number display in and to reduce the processing load on the main CPU 63.

By using a total of 16 LEDs in the special figure display portion 641a and the general figure display portion 642a, the entire 2-byte total number data is displayed in a binary number. This makes it possible to grasp the entire total number data and also the degree of convergence of the latest base value.

In the special figure display unit 641a and the general figure display unit 642a, the eight LEDs and the general figure display of the special figure display unit 641a are displayed when the setting value is being updated and the setting value is being confirmed. Using the eight LEDs of the section 642a, the total number display showing the total number data is performed. Therefore, the manager of the game hall makes a total based on the display of the special figure display unit 641a and the general figure display unit 642a in the situation where the setting value is being updated and the setting value is being confirmed. The information of the number data can be grasped, and the degree of convergence of the latest base value can be grasped.

In the situation where the setting value is being updated, a display indicating that the setting value is being updated on the first to fourth notification display devices 201 to 204 and a display showing the current setting value are displayed. Be seen. Therefore, in the situation where the display corresponding to the update of the set value is being performed on the first to fourth notification display devices 201 to 204, the total is displayed based on the displays of the special figure display unit 641a and the general figure display unit 642a. The information of the number data can be grasped, and the degree of convergence of the latest base value can be grasped. Further, in the situation where the setting value is being confirmed, a display indicating that the setting value is being confirmed on the first to fourth notification display devices 201 to 204 and a display showing the current setting value Is done. Therefore, in the situation where the display corresponding to the confirmation of the set value is being performed on the first to fourth notification display devices 201 to 204, the total is displayed based on the displays of the special figure display unit 641a and the general figure display unit 642a. The information of the number data can be grasped, and the degree of convergence of the latest base value can be grasped.

It should be noted that, instead of the special figure display portion 641a and the general figure display portion 642a in which eight LEDs are arranged side by side in a row, seven display segments arranged so as to generate the letter "8", and The special figure display section and the general figure display section having one display segment provided as a circular light emitting region may be provided at the lower right position of the seven display segments. Specifically, each of the special figure display unit and the general figure display unit has eight display segments. Of the eight display segments, all seven display segments are rod-shaped light emitting regions having the same shape and the same size, and are arranged so as to generate a letter "8". On the other hand, one display segment is a circular light emitting region, and is provided at the lower right position with respect to the seven display segments arranged in the shape of "8". The lower 8 bits of the total number data have a one-to-one correspondence with the eight display segments in the special figure display section. Each display segment in the special figure display unit is in a lighting state when the value of the corresponding bit of the lower 8 bits of the total number data is "1", and is in a lighting state when the value of the corresponding bit is "0". Becomes In addition, the upper 8 bits of the total number data have a one-to-one correspondence with the eight display segments in the public figure display section. Each display segment in the general display section is in a lighting state when the value of the corresponding bit in the upper 8 bits of the total number data is "1", and is in a lighting state when the value of the corresponding bit is "0". Becomes With this configuration as well, when the total number data is displayed on the special figure display unit and the general figure display unit, the display control of the special figure display unit can be executed by using the lower 8 bits of the total number data. By using the upper 8 bits of the total number data, the display control of the general figure display unit can be executed. In addition, the display corresponding to the result of the special figure special power control process (step SL814 of the first timer interrupt process (FIG. 338)) and the normal/universal power control process (step SL815 of the first timer interrupt process (FIG. 338)). The display corresponding to the result can be performed using the eight display segments.

Further, instead of the configuration in which the total number data is displayed as a binary number using the special figure display unit 641a and the general figure display unit 642a, the LEDs of the special figure display unit 641a and the general figure display unit 642a are changed to the total number data. The configuration may be such that the corresponding number of lights are turned on. Specifically, in the special figure display unit 641a and the general figure display unit 642a, the number corresponding to the quotient when the total number data, which is the numerical information of any of “0” to “65535”, is divided by “4096”. The LED lights up. When the total number data is in the numerical range of “4096×(p−1)” to “4096×p” (p is an integer of 1 to 16), the p LEDs are turned on. When "p" is in the numerical range of 1 to 8, "p" LEDs are lit from the right end of the eight LEDs in the special figure display unit 641a. When "p" is in the numerical range of 9 to 16, all eight LEDs in the special figure display unit 641a are turned on, and "p" is displayed from the right end of the eight LEDs in the general figure display unit 642a. -8" LEDs are lit. Thereby, the display of the total number data performed by using the special figure display unit 641a and the general figure display unit 642a can be made easy to understand.

Moreover, the number of LEDs in the special figure display unit 641a and the general figure display unit 642a is not limited to eight, and the number of LEDs in the special figure display unit 641a and the general figure display unit 642a is nine or more. Alternatively, the number of LEDs in the special figure display unit 641a and the general figure display unit 642a may be less than eight. For example, a special figure display unit having six LEDs is provided in place of the special figure display unit 641a in the 96th embodiment, and 6 in place of the public figure display unit 642a in the 96th embodiment. A general-purpose display unit having a number of LEDs is provided. The 6 LEDs in the special figure display section correspond to the 4th to 9th bits of the total number data, and the 6 LEDs in the general figure display section correspond to the 10th to 15th bits of the total number data. It corresponds to. The total 12 LEDs in the special figure display section and the general figure display section are turned on when the value of the corresponding bit in the total number data is "1", and the value of the corresponding bit in the total number data is When it is "0", it is turned off. As a result, the upper 12 bits of the total number data can be grasped based on the display on the special figure display section and the general figure display section. Therefore, the degree of convergence of the latest base value can be roughly grasped.

In addition, the total number may be displayed on the special figure display unit 641a and the general figure display unit 642a based on the open state of the front door frame 14. Accordingly, the operation for displaying the total number on the special figure display unit 641a and the general figure display unit 642a can be facilitated. Therefore, the burden of monitoring the base value on the game hall manager can be reduced.

<97th Embodiment>
In this embodiment, the processing configurations of the main process and the first timer interrupt process are different from those in the 49th embodiment. Hereinafter, a configuration different from that of the 49th embodiment will be described. Note that the description of the same configuration as the 49th embodiment is basically omitted.

FIG. 357( a) is an explanatory diagram for explaining the determination register 651 provided as a part of the registers of the main CPU 63.

The main CPU 63 is provided with a determination register 651 as a storage area for the main CPU 63 to specify a process to be executed in a main process (FIG. 358) described later. The determination register 651 has a data capacity of 1 byte (8 bits). The determination register 651 is supplied with storage power when operating power is being supplied to the main CPU 63, and is storing storage when operating power is not being supplied to the main CPU 63. Power is not supplied. Therefore, when the power of the pachinko machine 10 is ON and the operating power is being supplied to the main CPU 63, the information is stored and held in the determination register 651, and the power of the pachinko machine 10 is turned OFF. When the supply of operating power to the side CPU 63 is stopped, the information in the determination register 651 is erased without being stored and held. Therefore, immediately after the power of the pachinko machine 10 is turned on, each bit of the determination register 651 is in the state of all “0”. Since the judgment register 651 is provided in the main CPU 63, the reading speed of information in the main CPU 63 is faster when reading from the judgment register 651 than when reading from the main RAM 65.

The seventh bit B7, which is the most significant bit of the determination register 651, indicates to the main CPU 63 whether or not the setting key insertion section 68a provided in the main control device 60 is turned on by the setting key. It is set as a setting key flag in which information for specifying is specified. When it is specified in the operation determination process (FIG. 363) described later that the setting key insertion section 68a is turned on by the setting key, the setting key flag (7th bit B7) is set to “1”. If it is determined that the setting key inserting unit 68a is in the OFF state, the setting key flag (7th bit B7) is maintained in the state of "0".

The sixth bit B6, which is the second most significant bit of the determination register 651, contains information for the main CPU 63 to specify whether or not the reset button 68c provided in the main controller 60 is pressed. It is set as a reset button flag that is set. When it is specified in the operation determination process (FIG. 363) described later that the reset button 68c is pressed, the reset button flag (6th bit B6) is set to "1", and the reset button 68c is pressed. If it is specified that the reset button flag has not been set, the reset button flag (6th bit B6) is maintained in the state of "0".

The fifth bit B5, which is the third most significant bit of the determination register 651, is used to change the setting value that determines the advantage of the pachinko machine 10 with respect to the occurrence of an abnormality in the pachinko machine 10. It is set as an abnormality flag in which information for specifying whether or not there is no situation in the main CPU 63 is set. Note that the set values are set as 6 levels of “setting 1” to “setting 6” as in the above-described embodiments, but the number of levels is arbitrary as long as there are multiple levels. When it is specified in the abnormality determination processing (FIG. 359) described later that an abnormality has occurred in the main RAM 65, the abnormality flag (fifth bit B5) is set to "1". Further, when it is determined that a predetermined event to be monitored has occurred in the fraud detection process (step SP405) of the first timer interrupt process (FIG. 365) described later, and the setting value is changed thereafter. When it is specified that the processing for performing is not executed, the abnormality flag (fifth bit B5) is set to "1". Further, in the payout state receiving process (step SP418) of the first timer interrupt process (FIG. 365) described later or the payout state receiving process (step SP602) of the setting corresponding process (FIG. 367) described later, an abnormality relating to the payout of the game ball is found. If it is specified that the error has occurred and then the process for changing the set value is not executed, "1" is set in the error flag (fifth bit B5). To be done. On the other hand, when the occurrence of the above-mentioned various abnormalities is not specified, the abnormal flag (fifth bit B5) is maintained in the state of "0".

The fourth bit B4, which is the fourth most significant bit of the determination register 651, is whether the state in which the power of the pachinko machine 10 was previously shut off is in the process of executing the process for changing the set value. It is set as a power interruption flag during setting change in which information for specifying whether or not the main CPU 63 is set. Further, the third bit B3, which is the fifth most significant bit of the determination register 651, indicates that the situation where the power supply of the pachinko machine 10 was previously shut off is in the middle of executing the process for confirming the set value. It is set as a setting confirmation power failure flag in which information for specifying whether or not there is the main CPU 63 is set.

The second bit B2, which is the sixth most significant bit of the determination register 651, the first bit B1, which is the seventh most significant bit of the determination register 651, and the least significant bit, which is the least significant bit of the determination register 651, The 0 bit B0 is not assigned with a function as a flag and is blank.

FIG. 357( b) is an explanatory diagram for explaining the state specifying area 652 provided in the main RAM 65.

The state specifying area 652 is provided in the work area 221 for specifying control in the main RAM 65. The state specifying area 652 has a data capacity of 1 byte (8 bits). Since the state specifying area 652 is provided in the main RAM 65 to which the backup power is supplied, even if the power of the pachinko machine 10 is in the OFF state, the information of the state specifying area 652 is supplied by the backup power supply. Is stored.

The seventh bit B17, which is the most significant bit of the state specifying area 652, is a setting for setting information for the main MPU 63 to determine whether or not the process for changing the set value is being executed. It is set as a change status flag. In the main process (FIG. 358) described later, the setting change state flag (7th bit B17) is set to “1” before the setting process (step SN810) is started, and in the setting process (FIG. 366) described later. When it is specified that the setting key insertion portion 68a has switched from the ON state to the OFF state, the setting change state flag (7th bit B17) is cleared to "0".

When the power of the pachinko machine 10 is turned off and the supply of operating power to the main CPU 63 is stopped in the situation where the setting change state flag (7th bit B17) is set to "1", the setting change state concerned The state where the flag (7th bit B17) is set to "1" is maintained when the backup power is continuously supplied to the main RAM 65. Then, after that, when the power of the pachinko machine 10 is turned on and the supply of the operating power to the main CPU 63 is started, the determination register 651 (described below) performs state setting processing (FIG. 362) for determination. “1” is set to the setting change power failure flag (the fourth bit B4) of the register 651. When "1" is set to the setting change power failure flag (the fourth bit B4), the main CPU 63 restarts the process for changing the set value. As a result, when the power of the pachinko machine 10 is turned off during the process of changing the set value, the set value is changed even if the setting change operation is not performed when the power of the pachinko machine 10 is subsequently turned on. It is possible to execute the processing for changing.

The sixth bit B16, which is the second most significant bit of the state specifying area 652, is set with information for specifying in the main MPU 63 whether or not the process for confirming the set value is being executed. It is set as a setting confirmation status flag. Before the setting process (step SN810) is started in the main process (FIG. 358) described later, “1” is set in the setting confirmation status flag (b-th bit B16), and the setting process (FIG. 366) described later is performed. When it is specified that the setting key insertion portion 68a is switched from the ON state to the OFF state, the setting confirmation state flag (sixth bit B16) is cleared to "0".

When the power of the pachinko machine 10 is turned off and the supply of operating power to the main CPU 63 is stopped in the situation where the setting confirmation state flag (6th bit B16) is set to "1", the setting confirmation state is concerned. The state in which the flag (6th bit B16) is set to "1" is maintained when the backup power is continuously supplied to the main RAM 65. Then, after that, when the power of the pachinko machine 10 is turned on and the supply of the operating power to the main CPU 63 is started, the determination register 651 (described below) performs state setting processing (FIG. 362) for determination. "1" is set to the setting confirmation power failure flag (third bit B3) of the register 651. When "1" is set to the setting confirmation power interruption flag (third bit B3), the main CPU 63 restarts the process for confirming the set value. As a result, when the power of the pachinko machine 10 is turned off during the execution of the process for confirming the set value, the set value is changed even if the setting confirmation operation is not performed when the power of the pachinko machine 10 is turned on thereafter. It becomes possible to execute the processing for confirmation.

The fifth bit B15, which is the third most significant bit of the state specifying area 652, is used to change the setting value that determines the advantage of the pachinko machine 10 with respect to the occurrence of an abnormality in the pachinko machine 10. It is set as an abnormal state flag in which information for specifying by the main CPU 63 whether or not the situation is not set is set. When it is specified in the abnormality determination processing (FIG. 359) described later that an abnormality has occurred in the main RAM 65, "1" is set in the abnormality state flag (fifth bit B15). Further, when it is determined in the fraud detection process (step SP405) of the first timer interrupt process (FIG. 365) described later that a predetermined event to be monitored has occurred, an abnormal state flag (fifth bit B15). ) Is set to "1". Further, in the payout state receiving process (step SP418) of the first timer interrupt process (FIG. 365) described later or the payout state receiving process (step SP602) of the setting corresponding process (FIG. 367) described later, an abnormality relating to the payout of the game ball is found. When the occurrence is specified, the abnormal state flag (fifth bit B15) is set to "1". When the abnormal state flag (fifth bit B15) is set to "1", the process for updating the set value is executed, and the second RAM clear process (step SP517) of the setting process (FIG. 366) described later is executed. ) Is executed, "0" is cleared.

When the power of the pachinko machine 10 is turned off and the supply of operating power to the main CPU 63 is stopped in a situation where the abnormal condition flag (fifth bit B15) is set to “1”, the abnormal condition flag ( The state in which "1" is set in the fifth bit B15) is maintained when the backup power is continuously supplied to the main RAM 65. Then, after that, when the power of the pachinko machine 10 is turned on and the supply of the operating power to the main CPU 63 is started, the determination register 651 to be described later is set in the state setting process (FIG. 362). “1” is set to the abnormality flag (fifth bit B5) of the register 651. When the abnormality flag (fifth bit B5) is set to "1", the main CPU 63 executes the abnormality processing (step SN812) of the main processing (FIG. 358) described later, and then proceeds with the processing. Stop. As a result, when any of the above various abnormalities occurs, the process for advancing the game is not started until the process for changing the setting value is executed when the power of the pachinko machine 10 is subsequently turned on. It becomes possible to Note that the fourth to 0th bits B14 to B10 of the state specifying area 652 are blank because no function as a flag is assigned.

FIG. 358 is a flowchart showing main processing executed in the main CPU 63 in this embodiment. Note that the processing of steps SN801 to SN822 in the main processing is executed using the program for specific control and the data for specific control in the main CPU 63. When the main process is started, the interrupts of the first timer interrupt process (FIG. 365) and the second timer interrupt process (FIG. 134) described later are prohibited.

First, the power-on process is executed (step SN801). In the power-on process, the same processes as the steps SB101 to SB103 of the main process (FIG. 165) in the forty-ninth embodiment are executed. Specifically, for example, it waits without proceeding to the next process until a predetermined time for waiting (specifically, 1 second) elapses after the main process is activated. In the predetermined period for this weight, the operation start and initial setting of the symbol display device 41 are completed. Also, access to the main RAM 65 is permitted.

In the power-on process, the internal function register setting process is executed. In the internal function register setting process, the interrupt period of the first timer interrupt process (FIG. 365), which is a process that is activated by periodically interrupting the main process, is set to the first interrupt period (specifically, 4 milliseconds). And the interrupt period of the second timer interrupt process (FIG. 134), which is a process that is activated by periodically interrupting the main process, is set to a second interrupt period that is shorter than the first interrupt period. (Specifically, it is set to 2 milliseconds).

That is, in the present embodiment, as in the forty-ninth embodiment, the first timer interrupt processing (FIG. 365) and the second timer interrupt processing (FIG. 134) are performed as the timer interrupt processing so that the interrupt cycle becomes relatively long and short. And exist. Both the first timer interrupt process (FIG. 365) and the second timer interrupt process (FIG. 134) are activated by interrupting the main process. The second timer interrupt process (FIG. 134) is activated by interrupting the first timer interrupt process (FIG. 365). On the other hand, the first timer interrupt process (FIG. 365) does not start by interrupting the second timer interrupt process (FIG. 134). Further, if both the first interrupt cycle and the second interrupt cycle have passed in a situation where both the first timer interrupt processing (FIG. 365) and the second timer interrupt processing (FIG. 134) are not executed, those cycles The second timer interrupt processing (FIG. 134) is started first regardless of the lapsed order of the above. In this respect, it can be said that the second timer interrupt process (FIG. 134) is a process activated prior to the first timer interrupt process (FIG. 365). However, the present invention is not limited to this, and the first timer interrupt process (FIG. 365) may be activated prior to the second timer interrupt process (FIG. 134).

In the internal function register setting process, the first interrupt period of the first timer interrupt process (FIG. 365) is set in a predetermined register of the main CPU 63, and the second interrupt period of the second timer interrupt process (FIG. 134) is set. It is set in a specific register of the side CPU 63. However, even if these interrupt cycles are set in the register of the main CPU 63, the interrupted state of the first timer interrupt process (FIG. 365) and the second timer interrupt process (FIG. 134) is maintained. Further, in the internal function register setting process, in addition to the setting of the first and second interrupt cycles, the setting process of the numerical range of various counters such as the numerical range of the hit random number counter C1 is executed.

In the power-on process, "1" is set to the startup process flag provided in the work area 221 for specific control. The start-up processing flag indicates that even if the first timer interrupt process (FIG. 365) is activated, the power failure information storage process, various update processes, among the various processes set in the first timer interrupt process (FIG. 365), While the fraud detection process, the setting support process, and the security signal support process are executed, the main side is that the first timer interrupt process (FIG. 365) should be ended without executing the process for advancing the game. This is a flag for specifying by the CPU 63.

The start-up processing flag is set to "1" when the processing at the start of supplying the operating power (step SN801 to step SN821) is started in the main processing (FIG. 358), and the processing at the start of supplying the operating power. “0” is cleared before (step SN801 to step SN821) is finished and the residual process (step SN822) is started. In the first timer interrupt processing (FIG. 365), when "1" is set in the start-up processing flag, the processing of step SP409 to step SP421 is not executed so that the supply of operating power is started. Preventing the process for advancing the game from being executed in the situation where the process for changing the set value or the process for confirming the set value, which will be described later, is being executed among the processes (steps SN801 to SN821). Is possible. On the other hand, as described above, in the first timer interrupt processing (FIG. 365), even if the start-up processing flag is set to "1", by executing the processing of step SP401 to step SP407, the operating power is reduced. Power supply information storage processing, even in a situation where the processing for changing the setting value or the processing for confirming the setting value, which will be described later, is being executed among the processing (step SN801 to step SN821) at the start of supply of Various update processing, fraud detection processing, setting correspondence processing, and security signal correspondence processing are executed.

In particular, even when the start-up processing flag is set to "1", the power failure information storage processing (step SP401) is executed, so that the operation power supply start processing (steps SN801 to SN821) is started. Even if a power failure occurs in a situation in which a process for changing the set value or a process for confirming the set value, which will be described later, is being executed, the process at the time of power failure can be executed for the power failure. In the power failure process, the power failure flag provided in the specific control work area 221 is set to "1", and the checksum is calculated and the calculated checksum is stored in the specific control work area 221. When the supply of operating power is restarted, it is possible to prevent the occurrence of an abnormality in the main RAM 65. As a result, if a power outage occurs during the process for changing the set value or the process for confirming the set value, the fact that the power outage occurred during the process related to these settings will be supplied to the next operating power. It is possible to specify at the start.

By the way, in the situation where the process for changing the set value or the process for confirming the set value is being executed, both the first timer interrupt process (FIG. 365) and the second timer interrupt process (FIG. 134) are performed. Interrupts are not prohibited and can be interrupted at any timing. In this case, when the first timer interrupt process (FIG. 365) or the second timer interrupt process (FIG. 134) is activated by interruption in the process for changing the set value or the process for confirming the set value, The information of the return address of the main process (FIG. 358) for returning after the timer interrupt process that is the activation target is saved is saved in the stack area 222 for specific control, and the timer interrupt process is activated. Information of various registers of the main CPU 63 immediately before is saved in the stack area 222 for specific control. Then, when the timer interrupt process which is the activation target ends, the process returns to the process of the main process (FIG. 358) corresponding to the information of the return address saved in the stack area 222 for specific control, and The information saved in the stack area 222 for specific control is restored to various registers of the main CPU 63.

After the power-on process (step SN801) is executed in the main process (FIG. 358), the abnormality determination process is executed (step SN802). FIG. 359 is a flowchart showing the abnormality determination processing. Note that the processes of steps SN901 to SN906 in the abnormality determination process are executed using the program for specific control and the data for specific control in the main CPU 63.

First, a process for determining whether or not the checksum calculated when the pachinko machine 10 is powered off last time is executed (step SN901 and step SN902). FIG. 360 is an explanatory diagram for explaining the contents of various areas of the main RAM 65. As shown in FIG. 360, the main RAM 65 is provided with a checksum storage area 653 and another area 654. The checksum storage area 653 stores numerical information of the checksum calculated when the occurrence of a power failure is identified in the power failure information storage processing (step SP401) of the first timer interrupt processing (FIG. 365) described later. .. The checksum storage area 653 is provided in the work area 221 for specific control. The other area 654 is an area other than the checksum storage area 653 among various areas provided in the main RAM 65. The other area 654 includes a specific control work area 221, a specific control stack area 222, a non-specific control work area 223, and a non-specific control stack area 224.

FIG. 361 is a flowchart showing the power failure information storage process executed in step SP401 of the first timer interrupt process (FIG. 365). Note that the processing of steps SN911 to SN924 in the power failure information storage processing is executed using the program for specific control and the data for specific control in the main CPU 63.

In steps SN911 to SN918, the same processing as steps S6701 to S6708 of the power failure information storage processing (FIG. 101) in the thirtieth embodiment is executed. This identifies whether or not a power outage has occurred. When it is specified that a power failure has occurred (step SN918: YES), the power failure process of steps SN919 to SN924 is executed.

Specifically, first, "1" is set to the power failure flag provided in the work area 221 for specific control (step SN919). When the power failure process is executed normally and the information in the main RAM 65 is normally stored and held, the work area for specific control is set when the supply of operating power to the main CPU 63 is restarted. This means that the power failure flag 221 is set to “1”. Also, all the information of the output port in the register of the main CPU 63 is cleared to "0" (step SN920).

After that, the total value of all areas of the main RAM 65 is calculated (step SN921). Since the area for which the total value is calculated is the entire area of the main RAM 65, the area for which the calculation is performed includes not only the other area 654 but also the checksum storage area 653. For details of the specific contents for calculating the total value, since the main RAM 65 is provided with 10000 unit areas each having 1 byte, the main RAM 65 has a data capacity of 10 Kbytes. Is becoming The data capacity of the main RAM 65 is arbitrary as long as it has a plurality of bytes. Then, these unit areas are allocated as the checksum storage area 653 and are also allocated as the areas included in the other area 654.

The checksum storage area 653 has a data capacity of 1 byte because one unit area is allocated. When calculating the total value, 8-bit numerical information is sequentially added to the 8-bit calculation register in the main CPU 63 from the unit area set in the head address of the main RAM 65. Since the unit area of the final address in the main RAM 65 is allocated to the checksum storage area 653, the total value can be calculated when the 8-bit numerical information of the checksum storage area 653 is added to the calculation register. Will be terminated. In this way, by calculating all areas of the main RAM 65 when calculating the checksum, it is not necessary to specify the address range of the main RAM 65 for which the total value is calculated when calculating the checksum. Therefore, the processing load for calculating the checksum can be reduced.

Although details will be described later, in the situation where the total value of all the areas of the main RAM 65 is calculated in the power failure process (step SN919 to step SN924), the checksum storage area 653 is basically all “0” data (that is, 8 bits). Are all "0"). Therefore, the total value of all the areas of the main RAM 65 calculated in step SN921 becomes the same as the total value of the other areas 654 in the main RAM 65, and the two's complement number stored in the checksum storage area 653 in step SN923. Is the same as the 2's complement of the total value of the other areas 654 in the main RAM 65. Then, in this situation, when the total value of all areas of the main RAM 65 is calculated, the total value becomes "0".

Then, the two's complement of the total value calculated in step SN921 is calculated (step SN922). Specifically, the total value is data displayed as an 8-bit binary number, but the binary value of each bit of the total value is inverted. That is, a bit in which “1” is set in each bit of the total value becomes “0”, and a bit in which “0” is set in each bit of the total value is set to “1”. Then, by adding "1" to the inverted 8-bit binary number, the two's complement of the total value is calculated. When the 2's complement calculated in step S922 is added to the total value calculated in step S921, the addition result is "0" as a matter of course. After that, the numerical information of the two's complement calculated in step SN922 is stored in the checksum storage area 653 (step SN923). As a result, the checksum storage area 653 is in a state where the two's complement numerical information calculated in step SN922 is stored. After that, access to the main RAM 65 is prohibited (step SN924). Then, the infinite loop is continued until the power is completely cut off and the processing cannot be executed.

Returning to the description of the abnormality determination processing (FIG. 359), in step SN901, the total value of all areas of the main RAM 65 is calculated. The specific content for calculating this total value is the same as step SN921 of the power failure information storage processing (FIG. 361). That is, 8-bit numerical information is sequentially added to the 8-bit calculation register in the main CPU 63 from the unit area set at the head address of the main RAM 65. Since the unit area of the final address in the main RAM 65 is allocated to the checksum storage area 653, the total value can be calculated when the 8-bit numerical information of the checksum storage area 653 is added to the calculation register. Will be terminated.

In the power failure process (steps SN919 to SN924), the total value of all areas of the main RAM 65 is calculated and the two's complement of the calculated total value is calculated as already described. Then, the calculated two's complement numerical information is stored in the checksum storage area 653 which is data of all “0”. Therefore, when the power failure process (step SN919 to step SN924) was normally executed when the power was turned off last time, and the storage and holding of the data of the main RAM 65 was normally continued after that, in step SN901. The calculated total value of all areas of the main RAM 65 is “0”. On the other hand, if the power failure process (step SN919 to step SN924) is not normally executed when the power is turned off last time, if the data retention of the main side RAM 65 is not normally continued during the power interruption, or If the checksum storage area 653 is not all "0" data when the power failure process (step SN919 to step SN924) is started, the main side calculated in step SN901 The total value of all areas of the RAM 65 does not become "0".

When the total value of all areas of the main RAM 65 calculated in step SN901 is not “0” (step SN902: NO), it means that a data error has occurred in the main RAM 65. In this case, the abnormality flag (fifth bit B5) of the determination register 651 is set to "1" (step SN905), and the abnormal state flag (fifth bit B15) of the state specifying area 652 is set to "1". (Step SN906).

When the total value of all areas of the main RAM 65 calculated in step SN901 is "0" (step SN902: YES), it is determined whether the power failure flag of the main RAM 65 is set to "1" ( Step SN903). When the power outage process (step SN919 to step SN924) is executed in the power outage information storage process (FIG. 361), “1” is set to the power outage flag of the main RAM 65 as already described.

When "1" is not set in the power failure flag (step SN903: NO), it means that a data error has occurred in the main RAM 65. In this case, the abnormality flag (fifth bit B5) of the determination register 651 is set to "1" (step SN905), and the abnormal state flag (fifth bit B15) of the state specifying area 652 is set to "1". (Step SN906).

If the power failure flag is set to "1" (step SN903: YES), the setting corresponding to the information stored in the setting reference area 341 (see FIG. 154) in the specific control work area 221 of the main RAM 65. It is determined whether the value is within the normal range (step SN904). The setting reference area 341 is a storage area in which information for specifying the current setting value of the pachinko machine 10 by the main CPU 63 is stored as in the 45th embodiment. When numerical information of “0” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 1”. When the numerical information of “1” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 2”. When the numerical information of “2” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 3”. When the numerical information “3” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 4”. When the numerical information of “4” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 5”. When the numerical information of “5” is stored in the setting reference area 341, the current setting value of the pachinko machine 10 is “setting 6”. In step SN904, it is determined whether the setting value information stored in the setting reference area 341 is any of "0" to "5".

When the set value corresponding to the information stored in the setting reference area 341 is not within the normal range (step SN904: NO), it means that the main side RAM 65 has a data error. In this case, the abnormality flag (fifth bit B5) of the determination register 651 is set to "1" (step SN905), and the abnormal state flag (fifth bit B15) of the state specifying area 652 is set to "1". (Step SN906). When the set value corresponding to the information stored in the setting reference area 341 is within the normal range (step SN904: YES), this abnormality determination process is ended.

Returning to the explanation of the main processing (FIG. 358), after executing the abnormality determination processing in step SN802, the state setting processing for the determination register 651 is executed in step SN803. FIG. 362 is a flowchart showing a state setting process for the determination register 651. Note that the processing of steps SP101 to SP106 in the state setting processing for the determination register 651 is executed using the program for specific control and the data for specific control in the main CPU 63.

When the setting change state flag (7th bit B17) of the state specifying area 652 is set to "1" (step SP101: YES), the process for turning off the power of the pachinko machine 10 last time changes the set value. It means that it occurred during the execution of. In this case, "1" is set to the setting change power failure flag (fourth bit B4) of the determination register 651 (step SP102). As a result, even if the setting change operation is not performed when the power is turned on this time, the process for changing the set value can be executed.

Even if the setting change interruption flag (4th bit B4) of the determination register 651 is set to "1", the setting change state flag (7th bit B17) of the state specifying area 652 is set to "1". Is maintained. As a result, a power failure occurs after the setting change power interruption flag (4th bit B4) of the determination register 651 is set to "1" and before the processing for changing the setting value is started. Even in this case, when the power is turned on thereafter, it is possible to set "1" to the power interruption flag during setting change (the fourth bit B4) of the determination register 651 again.

When the setting confirmation state flag (6th bit B16) of the state specifying area 652 is set to "1" (step SP103: YES), the process of confirming the set value by turning off the power of the pachinko machine 10 last time It means that it occurred during the execution of. In this case, the setting confirmation power interruption flag (third bit B3) of the determination register 651 is set to "1" (step SP104). As a result, even if the setting confirmation operation is not performed when the power is turned on this time, the process for confirming the set value can be executed.

Even if the setting confirmation power failure flag (third bit B3) of the determination register 651 is set to "1", the setting confirmation status flag (sixth bit B16) of the status specifying area 652 is set to "1". Is maintained. As a result, a power failure occurs after the setting confirmation power failure flag (third bit B3) of the determination register 651 is set to "1" and before the processing for confirming the set value is started. Even in this case, it is possible to set the setting confirmation power failure flag (third bit B3) of the determination register 651 to "1" again when the power is turned on thereafter.

When "1" is set in the abnormal state flag (fifth bit B15) of the state specifying area 652 (step SP105: YES), the pachinko machine 10 of the previous time in a situation where any of various abnormalities has occurred. It means that the power is turned off. In this case, the abnormality flag (fifth bit B5) of the determination register 651 is set to "1" (step SP106). Accordingly, even if the occurrence of a data abnormality in the main RAM 65 is not specified in the abnormality determination processing (FIG. 359) executed when the power is turned on this time, the abnormality processing (step SN812) described later can be executed. The progress of processing can be stopped.

Even if "1" is set in the abnormality flag (fifth bit B5) of the judgment register 651, the state in which "1" is set in the abnormal state flag (fifth bit B15) of the state specifying area 652 is maintained. It As a result, even if a power failure occurs after the abnormality flag (fifth bit B5) of the determination register 651 is set to "1" and before the process for changing the set value is started, When the power is turned on, it is possible to set "1" to the abnormality flag (fifth bit B5) of the determination register 651 again.

Returning to the explanation of the main process (FIG. 358), after executing the state setting process for the determination register 651 in step SN803, the clear process at the time of closing is executed in step SN804. In the clear processing at the time of input, the checksum storage area 653 of the main RAM 65 is cleared to “0”. As a result, the checksum storage area 653 becomes all "0" data. Then, in the state where the checksum storage area 653 is all “0” data, the power failure information storage processing (FIG. 361) executes the power failure processing (steps SN919 to SN924), and all the data in the main side RAM 65. The 2's complement of the total area value is maintained until it is stored in the checksum storage area 653.

As described above, in the power failure process (steps SN919 to SN924), the total value is calculated for all areas of the main RAM 65 including the checksum storage area 653, and the two's complement of the calculated total value is calculated. Then, the calculated 2's complement is stored in the checksum storage area 653. Further, in the abnormality determination process (FIG. 359), the total value is calculated for all areas of the main RAM 65, and if the calculated total value is not “0”, it means that a data abnormality has occurred in the main RAM 65. Specified. In this way, when the checksum is calculated, the total value of all areas of the main RAM 65 including the checksum storage area 653 is calculated, and thus the address range of the main RAM 65 that is the calculation target of the total value when the checksum is calculated. Need not be specified. Therefore, in the power failure process (steps SN919 to SN924) and the abnormality determination process (FIG. 359), the processing load for calculating the checksum can be reduced.

However, in the configuration in which the checksum is calculated as described above, the checksum storage area 653 immediately before the checksum is calculated in the power failure process (step SN919 to step SN924) is the data of all “0”. If not, the total value of all areas of the main RAM 65 calculated in step SN921 will not be the same as the total value of the other areas 654 in the main RAM 65, and accordingly, in step SN923. The two's complement stored in the checksum storage area 653 is not the same as the two's complement with respect to the total value of the other areas 654 in the main RAM 65. Then, in this situation, when the total value of all areas of the main RAM 65 is calculated, the total value does not become "0". The flag (fifth bit B5) is set to "1", and the abnormal state flag (fifth bit B15) of the state specifying area 652 is set to "1".

On the other hand, a configuration may be considered in which all bits of the checksum storage area 653 are cleared to "0" when the power failure process (step SN919 to step SN924) is started. However, in this case, the processing load of the power outage process (steps SN919 to SN924) increases.

In such a situation, in the present embodiment, when the main process (FIG. 358) is started, and the abnormality determination process (FIG. 359) is performed after monitoring whether the checksum is normal or not is performed. Is executed (step SN804), all bits of the checksum storage area 653 of the main RAM 65 are cleared to "0", and the checksum storage area 653 becomes all "0" data. As a result, the processing load for calculating the checksum is reduced and the processing load of the power failure process (step SN919 to step SN924) is reduced, and the presence or absence of data abnormality in the main RAM 65 using the checksum is monitored. It becomes possible to do it appropriately.

Particularly, the clearing process at the time of insertion (step SN804) is a process for determining whether or not the abnormality process (step SN812) should be executed (step SN811), a process for changing the set value. Is executed before the process of starting (step SN807 to step SN810) and the process of starting the process for confirming the set value (step SN810, step SN818 to step SN819). As a result, the checksum storage area 653 can be set to all "0" data before the abnormality processing (step SN812), the processing for changing the setting value, and the processing for confirming the setting value are started. It will be possible. Since the abnormal process (step SN812), the process for changing the set value, and the process for confirming the set value are continued for a relatively long period, the probability of a power failure occurring in the middle of the process. Becomes higher. In this case, the checksum storage area 653 is set to all "0" data before these processes are started, so that the presence or absence of data abnormality in the main RAM 65 using the checksum is properly monitored. Is possible.

In the main process (FIG. 358), the operation determination process is executed after the clearing process (step SN804) at the time of insertion (step SN805). FIG. 363 is a flowchart showing the operation determination process. Note that the processes of steps SP201 to SP204 in the operation determination process are executed using the specific control program and the specific control data in the main CPU 63.

In the operation determination process, when the setting key insertion section 68a is turned on by the setting key (step SP201: YES), the setting key flag (7th bit B7) of the determination register 651 is set to "1". Yes (step SP202). When the reset button 68c is pressed (step SP203: YES), "1" is set to the reset button flag (sixth bit B6) of the determination register 651 (step SP204).

Returning to the explanation of the main processing (FIG. 358), after executing the operation determination processing in step SN805, it is determined whether or not the determination value of the determination register 651 is equal to or greater than the setting change reference value (step SN806). The determination register 651 has an 8-bit data capacity as described above, and the determination value of the determination register 651 is an 8-digit binary number in which the 8-bit data is arranged from the upper side to the lower side. .. In this case, as the higher-order bit of the determination register 651 is set to "1", the determination value becomes larger. The seventh bit B7, which is the most significant bit of the judgment register 651, is set as the setting key flag as already described, and the sixth bit B6, which is the second highest bit of the judgment register 651, is as described above. It is set as a reset button flag. On the other hand, the setting change reference value is set to "11000000". Therefore, when “1” is set in each of the setting key flag (7th bit B7) and the reset button flag (6th bit B6) of the judgment register 651, the fifth bit B5 to 5th bit in the judgment register 651 is set. Regardless of the state of the 0th bit B0, the judgment value of the judgment register 651 becomes the setting change reference value or more. On the other hand, if "1" is not set in either the setting key flag (7th bit B7) or the reset button flag (6th bit B6) of the judgment register 651, the fifth bit in the judgment register 651 is set. The determination value of the determination register 651 is less than the setting change reference value regardless of the state of B5 to 0th bit B0.

When the judgment value of the judgment register 651 is equal to or larger than the setting change reference value (step SN806: YES), the pachinko is operated in the situation where the setting key insertion portion 68a is turned on by the setting key and the reset button 68c is pressed. This means that the power of the machine 10 is turned on. In this case, after performing the processing for starting the change of the setting value shown in step SN807 to step SN809, the setting processing of step SN810 is executed. Details of these processes will be described later.

When the judgment value of the judgment register 651 is less than the setting change reference value (step SN806: NO), it is judged whether "1" is set in the abnormality flag (fifth bit B5) of the judgment register 651. (Step SN811). As described above, if it is determined in the abnormality determination process (FIG. 359) that a data abnormality has occurred in the main RAM 65, the abnormality flag (5th bit B5) of the determination register 651 is set to "1". To be done. Further, when a predetermined event to be monitored occurs in the fraud detection process (step SP405) of the first timer interrupt process (FIG. 365) described later, a process for changing the set value is performed thereafter. If it is not executed, the abnormality flag (fifth bit B5) is set to "1" in the state setting process (FIG. 362) for the determination register 651. Further, in the payout state receiving process (step SP418) of the first timer interrupt process (FIG. 365) described later or the payout state receiving process (step SP602) of the setting corresponding process (FIG. 367) described later, an abnormality relating to the payout of the game ball is found. If it occurs and the process for changing the set value is not executed after that, the abnormality flag (fifth bit B5) is set in the state setting process (FIG. 362) for the determination register 651. "1" is set.

If "1" is set in the abnormality flag (fifth bit B5) of the determination register 651 (step SN811: YES), the abnormality processing is executed (step SN812). In the abnormality processing, data setting for causing the first to fourth notification display devices 201 to 204 to display the abnormality is performed, and the first timer interrupt processing (FIG. 365) and the second timer interrupt processing (FIG. 134). ) Is permitted. In the abnormality process, the abnormality command is transmitted to each of the payout control device 77 and the sound emission control device 81. The payout control device 77 prohibits the payout of the game ball by receiving the abnormal command. Upon receiving the abnormality command, the voice emission control device 81 causes the display light emitting section 53 to emit light in a manner corresponding to the information abnormality at the start of the supply of the operating power, and the speaker section 54 "Please change the setting." Is output. Moreover, the character image "Please change the setting." is displayed on the symbol display device 41. These notifications are maintained until the supply of operating power to the pachinko machine 10 is stopped, and are ended when the supply of operating power to the pachinko machine 10 is stopped. Further, in the abnormality processing, all the information of the output port in the register of the main CPU 63 is set to "0". After executing the abnormal process in step SN812, the process is stopped and stands by.

When "1" is not set in the abnormality flag (fifth bit B5) of the judgment register 651 (step SN811: NO), the setting interruption power interruption flag (fourth bit B4) of the judgment register 651 is set to "1". Is set (step SN813). When "1" is set to the power interruption flag during setting change (4th bit B4) (step SN813: YES), it means that the power is turned off during the process for changing the set value. Therefore, the setting process is executed to restart the process for changing the setting value (step SN810). Details of this processing will be described later.

When "1" is not set in the setting change power failure flag (4th bit B4) of the judgment register 651 (step SN813: NO), the reset button flag (6th bit B6) of the judgment register 651 is set to " It is determined whether "1" is set (step SN814). When "1" is set in the reset button flag (sixth bit B6) (step SN814: YES), the first RAM clearing process is executed (step SN815).

In the first RAM clearing process, the setting reference area 341 (see FIG. 154), which is the area in which the setting value information indicating the setting state of the pachinko machine 10 is set in the specific control work area 221 in the main RAM 65, and the state identification. With the exception of the work area 652, the work area 221 for the specific control is cleared to “0” and the initial setting is executed. As a result, the area indicating whether or not the winning/winning lottery mode is the high-probability mode is cleared to "0". The mode is a low probability mode. In addition, the game times are not being executed, the opening/closing execution mode is not being executed, and the general-purpose display unit 38a is not being variably displayed, and the general electric accessory 34a is in the closed state. It becomes a situation. Further, since the hold storage area 65a and the universal electric power reserve area 65c provided in the work area 221 for specific control are also cleared to "0", the reserved information for the special figure display section 37a is deleted and the general figure display section is deleted. The hold information for 38a is deleted. In addition, the setting update area 342 provided in the specific control work area 221 is cleared to “0”. In the first RAM clearing process, the stack area 222 for specific control is cleared to "0" and the initial setting is executed. In the first RAM clear processing, the processing for clearing “0” and the processing for initial setting are not executed for the work area 223 for non-specific control and the stack area 224 for non-specific control. After executing the first RAM clearing process, a security signal output starting process is executed (step SN816). Details of this processing will be described later.

When "1" is not set in the reset button flag (6th bit B6) of the judgment register 651 (step SN814: NO), it is judged whether all the bits of the judgment register 651 are "0". (Step SN817). When all the bits of the determination register 651 are not “0” in the situation where the negative determination is made in all of step SN806, step SN811, step SN813 and step SN814, the setting confirmation operation is performed when the power is turned on (ie, The setting key flag (7th bit B7) of the judgment register 651 is set to "1" and the reset button flag (6th bit B6) is "0"), or a process for confirming the set value. It is a situation that the power is turned on after the power is turned off during the execution of (i.e., the setting confirmation power failure flag (third bit B3) of the determination register 651 is set to "1"). means. In this case, after performing the processing for starting the confirmation of the set value shown in steps SN818 and SN819, the setting processing of step SN810 is executed. Details of these processes will be described later.

When all the bits of the judgment register 651 are "0" (step SN817: YES), the power-on command transmission process is executed (step SN820). Details of this processing will be described later. After that, the initialization processing of the determination register 651 is executed (step SN821). In the initialization process, all bits of the determination register 651 are cleared to "0". After that, the residual process of step SN822 is repeatedly executed. That is, the main CPU 63 is configured to periodically execute the first timer interrupt process (FIG. 365) and the second timer interrupt process (FIG. 134), but between the one timer interrupt process and the next timer interrupt process. Residual time will occur. This remaining time will vary depending on the processing completion time of each timer interrupt processing, but the remaining processing is repeatedly executed by utilizing this irregular time. In this respect, it can be said that the residual process is an irregular process executed irregularly.

FIG. 364 is a flowchart showing the residual processing. The processing of steps SP301 to SP306 in the residual processing is executed by using the specific control program and the specific control data in the main CPU 63.

First, in order to prohibit the occurrence of the first timer interrupt process (FIG. 365) and the second timer interrupt process (FIG. 134), interrupt prohibition is set (step SP301). After that, the random number initial value updating process for updating the random number initial value counter CINI is executed (step SP302), and the fluctuation counter updating process for updating the fluctuation type counter CS is executed (step SP303). In these updating processes, the current numerical value information is read from the corresponding counter of the main RAM 65, the process of adding 1 to the read numerical value information is performed, and then the process of overwriting the counter of the reading source is executed. In this case, when the counter value exceeds the maximum value, each is cleared to "0".

After that, it is determined whether or not the set value corresponding to the information stored in the setting reference area 341 (see FIG. 154) in the specific control work area 221 of the main RAM 65 is within the normal range (step SP304). .. The processing content of step SP304 is the same as that of step SN904 in the abnormality determination processing (FIG. 359), and specifically, whether the setting value information stored in the setting reference area 341 is "0" to "5". Determine whether there is.

When the setting value corresponding to the information stored in the setting reference area 341 is not within the normal range (step SP304: NO), the abnormality processing is executed (step SP305). The processing content of the abnormality processing is the same as step SN812 of the main processing (FIG. 358). After the abnormal process is executed in step SP305, the process is stopped and stands by.

If the set value corresponding to the information stored in the setting reference area 341 is within the normal range (step SP304: YES), the first timer interrupt process (FIG. 365) and the second timer interrupt process (FIG. 134) occur. After the interrupt permission is set to permit (step SP306), the residual processing is terminated.

As described above, in the main process (FIG. 358) in this embodiment, the information corresponding to the state in which the supply of the operating power is started is set in the judgment register 651 of the main CPU 63 and is set in the judgment register 651. The type of processing to be executed in the main processing (FIG. 358) is specified using the information. This makes it possible to collectively specify the details of the state in which the supply of the operating power has been started, and to grasp the optimum process to be executed in the main process (FIG. 358) this time based on the specification result. ..

By using the determination register 651, execution of a process for changing a set value based on a setting change operation>setting of an abnormal state when an abnormality occurs>a process of changing a set value for a power interruption during setting change Resume> Execution of first RAM clear process based on RAM clear operation> Execution of process for confirming set value based on setting confirmation operation or resumption of process for confirming set value during power failure> Normal restoration It is possible to specify the process to be executed in the main process (FIG. 358) according to the priority of executing the power processing.

The process to be executed in the main process (FIG. 358) is specified according to the judgment value specified based on the information set in each bit of the judgment register 651. Specifically, by determining whether or not the determination values are all “0”, it is determined whether or not the processing for confirming the set value is in a situation to be executed. This makes it possible to reduce the processing load for specifying the processing to be executed in the main processing (FIG. 358).

FIG. 365 is a flowchart showing the first timer interrupt processing in this embodiment executed by the main CPU 63. Note that the processing of steps SP401 to SP421 in the first timer interrupt processing is executed using the program for specific control and the data for specific control in the main CPU 63. In addition, the first timer interrupt process is periodically activated in the 4 msec cycle which is the first interrupt cycle as in the 35th embodiment.

First, a power failure information storage process is executed (step SP401). The processing contents of the power failure information storage processing are as already described. In addition, by executing the random number updating process for lottery (step SP402), each numerical value information of the winning random number counter C1, the jackpot type counter C2, the reach random number counter C3, and the general electric utility open counter C4 is updated, and the random number initial value is updated. The numerical information of the random number initial value counter CINI is updated by executing the process (step SP403), and the numerical information of the fluctuation type counter CS is updated by executing the fluctuation counter updating process (step SP404). In addition, by executing the fraud detection process (step SP405), it is monitored whether or not the event set as the fraud monitoring target has occurred. In the fraud detection process, the occurrence of a plurality of types of events is monitored, and by confirming that any of these types of events has occurred, the abnormal state flag (the fifth bit Set "1" to B15). After that, the setting correspondence processing (step SP406) and the security signal correspondence processing (step SP407) are executed. Details of these processes will be described later.

Then, it is determined whether or not "1" is set to either the abnormal state flag (fifth bit B15) in the state specifying area 652 or the startup processing flag in the specific control work area 221 (step SP408). As described above, the abnormal state flag (fifth bit B15) indicates that the abnormality determination processing (FIG. 359) of the main processing (FIG. 358) determines that a data abnormality in the main RAM 65 has occurred. While "1" is set, the fraud detection process (step SP405) of the first timer interrupt process (FIG. 365), the payout state reception process (step SP418) or the setting corresponding process of the first timer interrupt process (FIG. 365) ( "1" is also set when the occurrence of an abnormality is specified in the payout state reception process (step SP602) of FIG. 367). The state where "1" is set to the abnormal state flag (fifth bit B15) is cleared to "0" when the process for changing the set value is completed. The start-up processing flag is set to "1" when the processing (step SN801 to step SN821) at the time of starting the supply of the operating power is started in the main processing (FIG. 358), and is set at the time of starting the supply of the operating power. “0” is cleared before the processing (step SN801 to step SN821) is finished and the residual processing (step SN822) is started.

When "1" is set in at least one of the abnormal state flag (fifth bit B15) and the startup processing flag (step SP408: YES), the first processing is executed without executing the processing of step SP409 to step SP421. The timer interrupt processing (FIG. 365) is ended. That is, the first timer interrupt processing (FIG. 365) is performed not only when the abnormal state flag (fifth bit B15) is set to “1” but also when the startup processing flag is set to “1”. ), the processes of steps SP401 to SP407 are executed, while the processes of steps SP409 to SP421 are not executed.

If "1" is not set in either the abnormal state flag (fifth bit B15) or the startup flag (step SP408: NO), the processes of steps SP409 to SP421 are executed. Specifically, port output processing is executed in step SP409, read processing is executed in step SP410, ball entry detection processing is executed in step SP411, timer update processing is executed in step SP412, and firing control is executed in step SP413. The processing is executed, the input state monitoring processing is executed in step SP414, the special figure special electric control processing is executed in step SP415, the universal figure general electric control processing is executed in step SP416, and the display control processing is executed in step SP417. In step SP418, payout state reception processing is executed, in step SP419 payout output processing is executed, in step SP420 external information setting processing is executed, and in step SP421 management processing is called. The processing contents of these steps SP409 to SP421 are the same as the processing contents of steps S8907 to S8918 and step S8920 of the first timer interrupt processing (FIG. 133) in the thirty-fifth embodiment.

<Setting-related processing>
Next, the setting related processing will be described. As the setting-related processing, processing for changing the setting value and processing for confirming the setting value are set.

As described above, the processing for changing the set value is executed when the judgment value of the judgment register 651 is equal to or larger than the setting change reference value. Specifically, when it is determined in the main process (FIG. 358) that the determination value of the determination register 651 is greater than or equal to the setting change reference value (step SN806: YES), first RAM clear processing is executed (step SN807). .. The processing content of the first RAM clear processing is the first RAM of step SN815 executed when it is determined that the reset button flag (6th bit B6) of the determination register 651 is set to "1" (step SN814: YES). It is the same as the clearing process.

As described above, in the first RAM clearing process, the setting reference area 341 (see FIG. 154) is the area in which the setting value information indicating the setting state of the pachinko machine 10 is set in the specific control work area 221 in the main RAM 65. ) And the state specifying area 652, the work area 221 for the specific control is cleared to “0” and the initial setting is executed. As a result, the area indicating whether or not the winning/winning lottery mode is the high-probability mode is cleared to "0". The mode is a low probability mode. In addition, the game times are not being executed, the opening/closing execution mode is not being executed, and the general-purpose display unit 38a is not being variably displayed, and the general electric accessory 34a is in the closed state. It becomes a situation. Further, since the hold storage area 65a and the universal electric power reserve area 65c provided in the work area 221 for specific control are also cleared to "0", the reserved information for the special figure display section 37a is deleted and the general figure display section is deleted. The hold information for 38a is deleted. In addition, the setting update area 342 provided in the specific control work area 221 is cleared to “0”. In the first RAM clearing process, the stack area 222 for specific control is cleared to "0" and the initial setting is executed. In the first RAM clear processing, the processing for clearing “0” and the processing for initial setting are not executed for the work area 223 for non-specific control and the stack area 224 for non-specific control.

In the first RAM clear processing, the state specifying area 652 is not cleared to "0". Therefore, even if the processing for changing the set value is started in a state where "1" is set in the abnormal state flag (fifth bit B15) of the state specifying area 652, the abnormal state flag (fifth bit) The state in which "1" is set in bit B15) is maintained. As a result, even if the process for changing the set value is started in the state where "1" is set in the abnormal state flag (fifth bit B15), if the power failure occurs in the middle of the process, the abnormal state is generated. It is possible to maintain the state in which the flag (5th bit B15) is set to "1". Further, as will be described later in detail, the state specifying area 652 is cleared to “0” when the process for changing the set value is completed. As a result, the state in which the abnormal state flag (5th bit B15) is set to "1" is maintained until the process for changing the set value is normally completed, and the process for changing the set value is performed. When completed normally, "0" will be cleared.

After executing the first RAM clearing process, a process for displaying the current setting value (that is, the setting value set when the previous power-off was generated) on the fourth notification display device 204 is executed ( Step SN808). Specifically, the information of the setting reference area 341 (see FIG. 154), which is the area in which the setting value information indicating the setting state of the pachinko machine 10 is set in the specific control work area 221, is set to the specific control information. It is set in the setting update area 342 (see FIG. 154) provided in the work area 221.

The setting update area 342 stores information on the setting value being changed in the process for changing the setting value. That is, in the process for changing the set value, the information of the set value to be selected is updated every time the reset button 68c is pressed. At the time of this update, the setting stored in the setting reference area 341 is updated. The setting value information stored in the setting updating area 342 is changed without changing the value information. As a result, it becomes possible to change the set value while storing and holding information on the set value that was set before the processing for changing the set value was started. When the process for changing the setting value is completed, the setting reference area 341 is overwritten with the setting value information stored in the setting updating area 342 at that time. As a result, the resulting set value updated in the process for changing the set value is set as the set value of the current pachinko machine 10. Further, when the process for changing the setting value is being executed, the setting value corresponding to the information stored in the setting updating area 342 is displayed on the fourth notification display device 204.

Numerical information is stored in the setting update area 342 as information on the set value. Specifically, when numerical information of “0” is stored in the setting update area 342, the setting value of the selection target is “setting 1”. When the numerical value information “1” is stored in the setting update area 342, the setting value to be selected is “setting 2”. When the numerical value information “2” is stored in the setting update area 342, the setting value to be selected is “setting 3”. When the numerical information of “3” is stored in the setting update area 342, the setting value to be selected is “setting 4”. When the numerical value information “4” is stored in the setting update area 342, the setting value to be selected is “setting 5”. When the numerical value information “5” is stored in the setting update area 342, the setting value to be selected is “setting 6”.

After that, the setting change status flag (7th bit B17) of the status specifying area 652 is set to "1" (step SN809). If "1" has already been set in the setting change state flag (7th bit B17), that state is maintained. If the setting change status flag (7th bit B17) is set to "1" in step SN809, the setting confirmation status flag (6th bit B16) of the status specifying area 652 is cleared to "0". Then, the setting process is executed (step SN810).

Even if the judgment value of the judgment register 651 is less than the setting change reference value, the setting process is performed by setting the setting change interruption flag (fourth bit B4) of the judgment register 651 to "1". It is also executed when there is. Specifically, when it is determined in the main process (FIG. 358) that the setting-changing power interruption flag (fourth bit B4) is set to "1" (step SN813: YES), the setting process is executed ( Step SN810).

If the setting process (step SN810) is executed due to the setting-changing power interruption flag (fourth bit B4) being set to "1", the processes of steps SN807 and SN808 are executed. Not executed That is, the setting update area 342 is not cleared to "0" because the first RAM clearing process of step SN807 is not executed. Further, since the process of step SN808 is not executed, the information of the setting reference area 341 is not set in the setting update area 342. As a result, if the power is turned off during the process for changing the set value and the process for changing the set value is restarted when the power is turned on again, the selection is made at the previous power off. It is possible to restart the processing for changing the target setting value from the target setting value.

When the setting process (step SN810) is executed due to the setting-changing power interruption flag (the fourth bit B4) being set to "1", the setting change state of the state specifying area 652 is changed. The process of setting "1" to the flag (7th bit B17) (step SN809) is also not executed. However, since the setting change status flag (7th bit B17) is set to "1" in the situation where the processing for changing the setting value is being executed, the processing for changing the setting value is being executed. When the power is turned off in step S10 and the setting process (step SN810) is executed due to the setting change power interruption flag (4th bit B4) being set to "1" when the power is turned on thereafter, The state in which "1" is set to the setting change state flag (7th bit B17) is maintained.

Even if the judgment value of the judgment register 651 is less than the setting change reference value and "1" is not set in the setting change power interruption flag (4th bit B4) of the judgment register 651, When the determination value of the determination register 651 is not "0" because "1" is set in the setting key flag (7th bit B7) or the setting confirmation power interruption flag (3rd bit B3) of the register 651, The setting process is executed. Specifically, when it is determined that the determination value of the determination register 651 is not “0” in the main processing (FIG. 358) (step SN817: NO), the processing of step SN818 and step SN819 is executed, and then the setting processing. Is executed (step SN810). In step SN818, "1" is set to the setting confirmation status flag (6th bit B16) of the status specifying area 652. If "1" has already been set in the setting confirmation state flag (6th bit B16), that state is maintained. When the setting confirmation status flag (sixth bit B16) is set to "1" in step SN818, the setting change status flag (seventh bit B17) of the status specifying area 652 is cleared to "0". In step SN819, similarly to step SN808, the information of the setting reference area 341 is set in the setting update area 342. As a result, the current setting value (that is, the setting value that was set when the power was turned off last time) is displayed on the fourth notification display device 204.

FIG. 366 is a flowchart showing the setting process of step SN810 in the main process (FIG. 358). Note that the processing of step SP501 to step SP519 in the setting processing is executed using the specific control program and specific control data in the main CPU 63.

When "1" is set in the setting change state flag (7th bit B17) of the state specifying area 652 (step SP501: YES), the setting change command is transmitted to the sound emission control device 81 (step SP502). ), and transmits a power-on command to the voice emission control device 81 (step SP503). Upon receiving the setting change command, the voice emission control device 81 causes the notification indicating that the process for changing the set value is being executed. Further, the voice light emission control device 81 receives the power-on command to specify that the communication with the main CPU 63 has started normally, and the predetermined area of the main RAM 65 is cleared to “0”. The notification indicating that is executed. Then, a security signal output start process is executed (step SP504). Details of this processing will be described later.

When "1" is not set in the setting change status flag (7th bit B17) (step SP501: NO), the setting confirmation command is transmitted to the sound emission control device 81 (step SP505), and the power recovery command is sent. It is transmitted to the sound emission control device 81 (step SP506). Upon receiving the setting confirmation command, the sound emission control device 81 causes the notification indicating that the process for confirming the set value is being executed. Further, the voice light emission control device 81 identifies that the communication with the main CPU 63 has started normally by receiving the power supply restoration command.

When the processing of step SP504 or step SP506 is executed, "1" is set to the transmitted flag provided in the work area 221 for specific control in the main RAM 65 (step SP507). The transmitted flag is a flag for the main CPU 63 to specify that the power-on command or the power restoration command has already been transmitted.

Then, it is determined whether or not the reset button 68c has been pressed (step SP508). As described above, in order to execute the process for changing the set value, the setting key insertion portion 68a is turned on and the reset button 68c is pressed as the setting change operation at the start of the supply of the operating power. Must have been Further, in the situation where the process for changing the set value is being executed, the set value to be selected is changed by one step each time the pressing operation on the reset button 68c is performed, as will be described later in detail. In this case, the situation where the reset button 68c is still being pressed immediately after the setting process (FIG. 366) is started means that the pressing operation of the reset button 68c for the setting change operation is continued. Means In such a situation, an affirmative decision is made in step SP508 to set "1" to the ON continuation flag provided in the work area 221 for specific control in the main RAM 65 (step SP509). The ON-continuation flag is used by the main CPU 63 to specify that the pressing operation of the reset button 68c for the setting change operation is continued even after the processing for changing the set value is started. It is a flag. Although details will be described later, in the situation where the ON continuation flag is set to "1", the setting value of the selection target is not changed even if it is specified that the reset button 68c is pressed. This makes it possible to prevent the setting value to be selected from being changed when the pressing operation of the reset button 68c for the setting change operation is continued.

When a negative determination is made in step SP508, or when the processing of step SP509 is executed, the setting start time processing is executed (step SP510). In the setting start time process, all of the special figure display portion 37a is notified in order to notify that the setting related process (process for changing the set value, process for confirming the set value) is being executed. The data for setting the display segment of to the light emitting state is set. By executing the second timer interrupt process (FIG. 134) in the situation where the data is set, all the display segments of the special figure display portion 37a are in the light emitting state. The state where all the display segments of the special figure display portion 37a are in the light emitting state is ended when the setting related processing of this time is completed. In a situation where a game is being played, not all display segments of the special figure display portion 37a are in a light emitting state. Therefore, the game hall manager who confirms that all the display segments of the special figure display portion 37a are in the light emitting state can recognize that the setting related processing is being executed. Become. The display unit in which all the display segments are in the light emitting state is not limited to the special figure display unit 37a, and in addition to or instead of the special figure display unit 37a, the special figure hold display unit 37b and the general figure display. It may be the part 38a and the universal figure reservation display part 38b.

In the setting start time process, when the process for changing the setting value is being executed this time, it corresponds to the information in the display and setting updating area 342 indicating that the setting value is being changed. The display data for displaying the set value is stored in the fifth display data buffer 275 (see FIG. 120) in the work area 221 for specific control. Further, in the setting start time process, when the process for confirming the set value is being executed this time, a display indicating that the setting value is being confirmed and information in the setting update area 342 are displayed. The display data for displaying the corresponding set value is stored in the fifth display data buffer 275. In the second timer interrupt process (FIG. 134) in the present embodiment, the processes of steps S9003 to S9006 are not set, and the setting change state flag (seventh bit B17) or the setting confirmation state flag (of the state specifying area 652) is set. When "1" is set in the sixth bit B16), the processes of steps S9008 to S9014 are executed without executing the process of step S9007. By executing the second timer interrupt process (FIG. 134) in the situation where the above-mentioned display data is stored in the fifth display data buffer 275, this time the process for changing the set value is being executed. If there is, a display indicating that the setting value is being changed and a setting value corresponding to the information in the setting update area 342 are displayed on the first to fourth notification display devices 201 to 204, and this time. When the process for confirming the set value is being executed, a display indicating that the set value is being confirmed and a display of the set value corresponding to the information in the setting update area 342 are first to fourth. The notification display devices 201 to 204 are used.

After that, in order to permit the occurrence of the first timer interrupt process (FIG. 365) and the second timer interrupt process (FIG. 134), the interrupt permission is set (step SP511). If the first interrupt cycle has already elapsed at this timing, the first timer interrupt processing (FIG. 365) is started. If the second interrupt cycle has already elapsed at this timing, the second timer interrupt process (FIG. 134) is started. If both the first interrupt period and the second interrupt period have already passed at this timing, the first timer interrupt process (FIG. 365) is executed after the second timer interrupt process (FIG. 134) is executed. Executed. After that, in order to prohibit the occurrence of the first timer interrupt process (FIG. 365) and the second timer interrupt process (FIG. 134), the interrupt disable setting is made (step SP512).

After that, it is determined whether or not the setting key insertion section 68a is switched from the ON state to the OFF state (step SP513). Specifically, it is determined whether the reception state of the signal received from the detection sensor that detects the state of the setting key insertion unit 68a has changed from the reception state corresponding to the ON state to the reception state corresponding to the OFF state. To do. Therefore, not only when the setting key inserting section 68a is maintained in the ON state, but also when the setting key inserting section 68a is in the OFF state and the OFF state is maintained when the setting process is started. Also, a negative determination is made in step SP513. When it is not specified that the setting key insertion unit 68a has switched from the ON state to the OFF state (step SP513: NO), the processing of step SP511 and step SP512 is repeated.

When it is specified that the setting key insertion unit 68a has switched from the ON state to the OFF state (step SP513: YES), the setting end command is transmitted to the voice emission control device 81 (step SP514). By receiving the setting end command, the sound emission control device 81 ends the notification if the notification indicating that the process for changing the setting value is being executed is being executed, and then the setting value is set. If the notification indicating that the process for confirming is being executed is being executed, the notification is ended.

After that, when the setting change status flag (7th bit B17) of the status specifying area 652 is set to "1" (step SP515: YES), the information of the setting update area 342 is set in the setting reference area 341. Yes (step SP516). As a result, the setting value selected in the process for changing the setting value this time is set as the setting value of the current pachinko machine 10.

After that, the second RAM clearing process is executed (step SP517). In the second RAM clearing process, in the specific control work area 221 in the main RAM 65, except for the setting reference area 341, which is an area in which information of setting values indicating the setting state of the pachinko machine 10 is set, The work area 221 is cleared to "0" and the initial setting is executed. In this case, the area targeted for clearing “0” includes not only the area targeted for clearing “0” in the first RAM clearing process (step SN807) but also the area for area identification 652. Therefore, the setting change status flag (7th bit B17) of the status specifying area 652 is cleared to "0". Further, when the process for changing the set value is started in the situation where the abnormal state flag (the fifth bit B15) of the state specifying area 652 is set to "1", the set value is changed. The abnormal state flag (fifth bit B15) is cleared to "0" upon completion of the processing. As a result, the abnormal state of the pachinko machine 10 will be canceled when the process for changing the set value is completed. Then, a security signal output start process is executed (step SP518). Details of this processing will be described later.

On the other hand, when "1" is not set in the setting change status flag (7th bit B17) of the status specifying area 652 (step SP515: NO), the setting related processing completed this time is for confirming the setting value. Means that. In this case, the setting confirmation status flag (6th bit B16) of the status specifying area 652 is cleared to "0" (step SP519).

As described above, in the setting process (FIG. 366), until it is specified that the setting key insertion unit 68a has switched from the ON state to the OFF state by using the setting key, the interrupt is permitted (step SP511) and the interrupt is prohibited. (Step SP512) is repeated. As described above, if the first interrupt period has already elapsed at the timing when the interrupt permission (step SP511) is performed, the first timer interrupt process (FIG. 366) will be executed. In the situation where the setting process (FIG. 366) is being executed, the setting process (FIG. 366) is executed because the start-up processing flag in the specific control work area 221 is set to “1”. In the first timer interrupt process (FIG. 365) that is started in the situation where there is a power outage information storage process (step SP401), random number updating process for lottery (step SP402), random number initial value updating process (step SP403), counter updating for variation The processing (step SP404), the fraud detection processing (step SP405), the setting correspondence processing (step SP406), and the security signal correspondence processing (step SP407) are executed. The process for advancing the game is not executed. This makes it possible to monitor for power outages, update random numbers, monitor for illegalities, perform settings-corresponding processing, and control the output of security signals during execution of processing to change the setting value or processing to confirm the setting value. However, it is possible to prevent the game from advancing during the execution of the process for changing the set value or the process for confirming the set value.

FIG. 367 is a flowchart showing the setting corresponding process executed in step SP406 of the first timer interrupt process (FIG. 365). Note that the processing of step SP601 to step SP610 in the setting correspondence processing is executed using the program for specific control and the data for specific control in the main CPU 63.

First, it is determined whether or not "1" is set in the setting change status flag (seventh bit B17) or the setting confirmation status flag (sixth bit B16) of the status specifying area 652 (step SP601). When "1" is not set in either the setting change status flag (seventh bit B17) or the setting confirmation status flag (sixth bit B16) (step SP601: NO), the process for changing the setting value and It means that none of the processing for confirming the set value is being executed. In this case, this setting support processing is ended as it is.

When "1" is set in the setting change status flag (seventh bit B17) or the setting confirmation status flag (sixth bit B16) (step SP601: YES), the payout status receiving process is executed (step SP602). In the payout state reception processing, it is monitored whether or not a command indicating that an abnormality relating to the payout of gaming balls has occurred is received from the payout control device 77, and when it is determined that the command is received, The abnormal state flag (fifth bit B15) of the state specifying area 652 is set to "1" and an abnormal notification command is transmitted to the sound emission control device 81. When the sound emission control device 81 receives the abnormality notification command, the sound emission control device 81 controls the display light emitting unit 53 and the speaker unit 54 so that the notification indicating that the abnormality related to the payout of the game ball has occurred is performed, and the notification is issued. The command is transmitted to the display control device 82 so as to be executed by the symbol display device 41. Further, in the payout state reception processing, it is monitored whether or not a command indicating that the gaming machine main body 12 is in the open state is received from the payout control device 77, and when it is specified that the command is received, The main body opening command is transmitted to the voice emission control device 81. When the sound emission control device 81 receives the main body opening command, the display light emitting unit 53 and the speaker unit 54 are controlled so that the notification indicating that the gaming machine main body 12 is in the open state is executed, and the notification is a symbol display. Send commands to the display controller 82 for execution by the device 41. Further, in the payout state reception process, it is monitored whether or not a command indicating that the front door frame 14 is in the open state is received from the payout control device 77, and when it is specified that the command is received, A front door opening command is transmitted to the voice emission control device 81. When the sound emission control device 81 receives the front door opening command, it controls the display light emitting unit 53 and the speaker unit 54 so that the notification indicating that the front door frame 14 is in the open state is executed and the notification is a symbol. The command is transmitted to the display control device 82 so as to be executed by the display device 41.

By executing the payout state receiving process (step SP602) in the setting corresponding process (FIG. 367) as described above, the process for changing the set value or the process for confirming the set value is executed. Even in a situation, monitoring whether or not an abnormality relating to payout of gaming balls has occurred, monitoring whether or not the gaming machine main body 12 is in an open state, and whether or not the front door frame 14 is in an open state. Can be monitored. The processing contents of the payout status reception processing are the same as the payout status reception processing executed in step SP418 of the first timer interrupt processing (FIG. 365).

Here, the execution mode of the processing in the situation where the processing for changing the setting value or the processing for confirming the setting value is being executed will be described with reference to the time chart of FIG. 368. 368(a) shows a period during which operating power is supplied to the main CPU 63, and FIG. 368(b) shows that the setting process (FIG. 366) is completed after the setting process (FIG. 366) is started. Up to (that is, until step SP518 or step SP519 is executed), FIG. 368(c) shows the timing at which the setting correspondence processing (FIG. 367) is executed, and FIG. 368(d) shows the setting correspondence processing ( 367) shows the timing at which the payout state reception process (step SP602) is executed.

At the timing of t1, supply of operating power to the main CPU 63 is started as shown in FIG. 368(a). At the time of starting the supply of the operating power this time, a process for changing the set value or a process for confirming the set value is executed. Therefore, at the subsequent timing of t2, the setting process (FIG. 366) is started as shown in FIG. 368(b).

In the setting process (FIG. 366), after the processes of step SP501 to step SP510 are executed, interrupt permission (step SP511) and interruption are permitted until it is specified that the setting key insertion unit 68a is switched from the ON state to the OFF state. Interruption prohibition (step SP512) is repeated. Therefore, at each of the timing of t3, the timing of t4, the timing of t5, the timing of t6, the timing of t7, and the timing of t8, the first timer interrupt processing (FIG. 365) is activated as shown in FIG. 368(c). The setting correspondence process (FIG. 367) is executed. Further, the setting corresponding process (FIG. 367) is executed in the situation where the process for changing the set value or the process for confirming the set value is being executed, so that the timing t3, the timing t4, and the timing t5. As shown in FIG. 368(d), the payout state receiving process (step SP602) of the setting corresponding process (FIG. 367) is executed at each of the timing of t, the timing of t6, the timing of t7, and the timing of t8. Then, at the timing of t9, the setting process (FIG. 366) is completed as shown in FIG. 368(b).

Note that the second timer interrupt process (FIG. 134) can also be activated at the timing from t2 to t9 when the first timer interrupt process (FIG. 365) can be activated. When the second timer interrupt process (FIG. 134) is activated, display control of various display devices including the first to fourth notification display devices 201 to 204 is executed.

As described above, by performing both the setting process (FIG. 366) of the main process (FIG. 358) and the setting corresponding process (FIG. 367) of the first timer interrupt process (FIG. 365), the setting related process (setting value) Process for changing the value and process for confirming the set value) are executed. By executing a part of the setting-related processing in the main processing (FIG. 358), it becomes possible to execute the setting-related processing as an intermediate processing in the processing at the start of supplying the operating power. Also, by performing a part of the setting-related processing in the first timer interrupt processing (FIG. 365), it is possible to prevent the processing cycle of the processing that should be executed periodically in the setting-related processing from becoming excessively short. This can be realized by using the first timer interrupt processing (FIG. 365).

Returning to the explanation of the setting corresponding process (FIG. 367), after executing the payout state receiving process in step SP602, "1" is set in the setting change state flag (7th bit B17) of the state specifying area 652. It is determined whether or not there is (step SP603). If "1" is not set in the setting change status flag (7th bit B17) (step SP603: NO), it means that the process for confirming the set value is being executed, and therefore this setting is directly supported. The process ends.

When "1" is set in the setting change status flag (7th bit B17) (step SP603: YES), it means that the process for changing the set value is being executed, and therefore steps SP604 to SP604. Processing for changing the setting value of the selection target shown in SP610 is executed. Specifically, first, it is determined whether or not the reset button 68c has been pressed (step SP604). If the reset button 68c has not been pressed (step SP604: NO), the ON continuation flag in the specific control work area 221 is cleared to "0" (step SP605). When the reset button 68c is pressed (step SP604: YES), it is determined whether the ON continuation flag in the specific control work area 221 is set to "1" (step SP606). When the ON continuation flag is set to "1" (step SP606: YES), this setting support processing is ended as it is. This makes it possible to prevent the setting value to be selected from being changed when the pressing operation of the reset button 68c for the setting change operation is continued.

When the reset button 68c is being pressed and the ON continuation flag is not set to "1" (step SP604: YES, step SP606: NO), selection is made for the current pressing of the reset button 68c. Update the target setting value by one step. Specifically, first, the value of the setting update area 342 is incremented by 1 (step SP607). When the value of the setting update area 342 after adding 1 exceeds the maximum value of "5" (step SP608: YES), the setting update area 342 is cleared to "0" (step SP609).

When a negative determination is made in step SP608 or when the processing of step SP609 is executed, display data setting processing is executed (step SP610). In the display data setting process, the display data for displaying the setting value corresponding to the information in the setting update area 342 and the display indicating that the setting value is being changed is displayed in the work area for specific control. It is stored in the fifth display data buffer 275 in 221 (see FIG. 120). In the second timer interrupt process (FIG. 134) in the present embodiment, the processes of steps S9003 to S9006 are not set as already described, and the setting change status flag (7th bit B17) of the status specifying area 652 is set to " If "1" is set, the processes of steps S9008 to S9014 are executed without executing the process of step S9007. When the display data as described above is stored in the fifth display data buffer 275, the second timer interrupt process (FIG. 134) is executed to display that the setting value is being changed. And the setting values corresponding to the information in the setting update area 342 are displayed on the first to fourth notification display devices 201 to 204.

Next, with reference to the time chart of FIG. 369, with reference to the time chart of FIG. 369, the execution of the processing for changing the setting value based on the setting change operation in the main processing (FIG. 358) is prioritized over the setting of the abnormal state for the occurrence of the abnormality. While explaining. FIG. 369(a) shows a period during which operating power is supplied to the main CPU 63, and FIG. 369(b) shows a period during which the abnormality flag (fifth bit B5) of the determination register 651 is set to "1". 369(c) shows a period in which an abnormal state is set, FIG. 369(d) shows a period in which a setting change operation is performed, and FIG. 369(e) is for changing a set value. 369 (f) shows a process for advancing the game (specifically, step SP409 to step SP421 of the first timer interrupt process (FIG. 365)) is executed. Indicates the period.

First, a case where the power is turned on while the setting change operation is performed will be described.

At timing t1, the supply of operating power to the main CPU 63 is started as shown in FIG. 369(a). The setting change operation has not been performed at the start of the supply of the operating power this time. After that, the occurrence of a data abnormality in the main RAM 65 is identified in the abnormality determination processing (FIG. 359) in the main processing (FIG. 358), so that the determination register 651 shown in FIG. 369(b) at the timing of t2. The abnormality flag (5th bit B5) is set to "1". Then, by setting "1" in the abnormality flag (fifth bit B5), the abnormality state is set as shown in FIG. 369(c) at the timing of t3. That is, the abnormality process (step SN812) is executed and the progress of the process is stopped. This makes it possible to urge the manager of the gaming hall to deal with the abnormality.

Next, a case where the power is turned on while the setting changing operation is performed will be described.

At the timing of t4, the setting change operation is started as shown in FIG. 369(d). Then, in the state where the setting change operation is being performed, the supply of the operating power to the main CPU 63 is started at the timing of t5 as shown in FIG. 369(a).

After that, the occurrence of a data abnormality in the main RAM 65 is identified in the abnormality determination processing (FIG. 359) in the main processing (FIG. 358), so that the determination register 651 shown in FIG. 369(b) at the timing of t2. The abnormality flag (5th bit B5) is set to "1". When "1" is set in the abnormality flag (fifth bit B5) of the determination register 651, "1" is also set in the abnormal state flag (fifth bit B15) of the state specifying area 652. It

However, since the power is turned on while the setting change operation is performed this time, the abnormal state is not set, but the set value is changed at the timing of t7 as shown in FIG. 369(e). The processing for is started. The first RAM clearing process (step SN807) is executed at the start of the process for changing the set value, but the determination register 651 and the state specifying area 652 are not cleared to “0” in the first RAM clearing process.

Then, at the timing of t8, the setting change operation is ended as shown in FIG. 369(d). In this case, since the setting change operation is continued even after the processing for changing the setting value is started, the processing for changing the setting value is started while the reset button 68c is pressed. However, in such a case, the ON continuation flag of the main RAM 65 is set to "1" so that the setting value to be selected is not updated by continuing the pressing operation of the reset button 68c. It becomes possible to do.

After that, at the timing of t9, the process for changing the set value is ended as shown in FIG. 369(e). In this case, the abnormal state flag (fifth bit B15) of the state specifying area 652 is cleared to "0" by executing the second RAM clearing process (step SP517). Further, by executing the processing of step SN821 of the main processing (FIG. 358), the abnormality flag (fifth bit B5) of the determination register 651 is also cleared to "0" as shown in FIG. 369(b). As a result, as shown in FIG. 369(f), when the processing for changing the set value is completed, the processing for advancing the game is started.

When the power is turned on while the setting changing operation is performed as described above, even if the data abnormality in the main RAM 65 is specified in the main process (FIG. 358) started when the power is turned on. The process for changing the set value without being set to the abnormal state is started. When the process for changing the set value is executed, the main RAM 65 is cleared to "0" and initialized, and the set value is newly set. In such a situation, by prioritizing the start of the processing for changing the set value over the setting of the abnormal state, it is possible to eliminate the data abnormality of the main side RAM 65 without requiring the power OFF/ON operation again. Is possible.

Even if the power is turned on while the setting change operation is not being performed, if the previous power off occurred during the process for changing the set value, the set value is changed. In the configuration in which the processing of FIG. 3 can be restarted, even if the previous power-off occurs in the middle of the processing for changing the set value, the main processing (FIG. 358) triggered by the power-on of this time is used. When the occurrence of the data abnormality in the RAM 65 is specified, the process for changing the set value is not prioritized but is set to the abnormal state. This makes it possible to limit the process prioritized over the setting of the abnormal state to the process for changing the set value when the power is turned on while the setting change operation is performed.

<Process related to command transmission at power ON>
Next, a process related to command transmission from the main CPU 63 to the sound emission control device 81 when the power is turned on will be described.

FIG. 370 is a flowchart showing the power-on command transmission processing executed in step SN820 of the main processing (FIG. 358). The power-on command transmission process is a process for transmitting a power-on command or a power-return command to the sound emission control device 81 at the start of supplying the operating power of the main CPU 63. The processing from step SP701 to step SP705 in the power-on command transmission processing is executed using the program for specific control and the data for specific control in the main CPU 63.

First, it is determined whether or not "1" is set in the transmitted flag of the specific control work area 221 in the main RAM 65 (step SP701). When the transmitted flag is set to "1" (step SP701: YES), after clearing the transmitted flag to "0" (step SP702), the main power input is performed without transmitting the power-on command and the power recovery command. The hour command transmission process ends. As described above, when the process for changing the set value is started, not only the setting change command but also the power-on command is transmitted in the setting process (FIG. 366). Further, as already described, when the process for confirming the set value is started, not only the setting confirmation command but also the power supply restoration command is transmitted in the setting process (FIG. 366). Then, in the setting process (FIG. 366), when the power-on command or the power-restoring command is transmitted, the transmitted flag is set to "1". In this case, as described above, in the power-on command transmission process (FIG. 370), when the transmission completion flag is set to “1”, the power-on command and the power restoration command are prevented from being transmitted, so that the power is already transmitted. It is possible to prevent the power-on command or the power recovery command from being transmitted again even though the power-on command or the power recovery command has already been transmitted.

If "1" is not set in the transmitted flag (step SP701: NO), it is determined whether or not "1" is set in the reset button flag (sixth bit B6) of the determination register 651. Then, it is determined whether or not the first RAM clear processing (step SN815) based on the RAM clear operation is executed in the main processing (FIG. 358) this time (step SP703). When a positive determination is made in step SP703, a power-on command is transmitted to the voice light emission control device 81 (step SP704). By receiving the power-on command, the voice emission control device 81 identifies that the communication with the main CPU 63 has started normally, and that the predetermined area of the main RAM 65 has been cleared to "0". The notification shown is executed. When a negative determination is made in step SP703, a power supply restoration command is transmitted to the voice emission control device 81 (step SP705). The voice emission control device 81 receives the power restoration command to identify that the communication with the main CPU 63 has started normally, and clears and initializes “0” in a predetermined area in the main RAM 65. The notification indicating that the power is restored is executed without being executed.

When the first RAM clearing process (step SN815) is executed without executing the process for changing the set value and the process for confirming the set value when the supply of the operating power is started as described above. Is transmitted to the voice emission control device 81. Further, when none of the process for changing the set value, the process for confirming the set value, and the first RAM clear process (step SN815) is performed when the supply of the operating power is started, the power is supplied. The return command is transmitted to the voice emission control device 81. Further, as described above, when the process for changing the set value is executed when the supply of the operating power is started, the power-on command as well as the command for changing the setting is executed in the process for setting (FIG. 366). Is transmitted, and when the processing for confirming the set value is executed when the supply of the operating power is started, the power supply restoration command as well as the setting confirmation command is transmitted in the setting processing (FIG. 366). To be done.

That is, when the supply of operating power is started and the abnormal state is not set, either the power-on command or the power-return command is transmitted from the main CPU 63 to the sound emission control device 81. Become. When the voice emission control device 81 receives either the power-on command or the power-return command after the start-up management period has elapsed after the start of the supply of the operating power, the sound emission control device 81 does not execute the communication abnormality notification, while If neither the power-on command nor the power-restoration command is received before the start-up management period has elapsed after the start of supply, communication abnormality notification is executed. This makes it possible to monitor whether or not the signal path between the main CPU 63 and the sound emission control device 81 is normal when the supply of the operating power is started, and at the same time there is an abnormality in the signal path. If it occurs, it is possible to urge the manager of the game hall to deal with it.

When the first RAM clear process (step SN815) is executed without executing the process for changing the set value and the process for confirming the set value when the supply of the operating power is started, the power is turned on. In the configuration in which the command is transmitted to the voice emission control device 81, the power-on command is also transmitted to the voice emission control device 81 even when the process for changing the set value is executed. When the processing for changing the set value is executed, the first RAM clear processing (step SN807) and the second RAM clear processing (step SP517) are executed as described above. In this case, the power-on command is transmitted to the sound emission control device 81 even when the processing for changing the set value is executed, so that “0” of a predetermined area in the main RAM 65 is cleared. Also, when the initialization is executed, the power-on command can be transmitted from the main CPU 63 to the sound emission control device 81.

When the process for changing the set value, the process for confirming the set value, and the first RAM clear process (step SN815) are not executed when the supply of the operating power is started, the power restoration command is issued. Is transmitted to the voice emission control device 81, the power recovery command is also transmitted to the voice emission control device 81 when the process for confirming the set value is executed. When the process for confirming the set value is executed, neither the first RAM clear process nor the second RAM clear process is executed as described above. In this case, even when the process for confirming the set value is executed, the power restoration command is transmitted to the voice emission control device 81, so that “0” of the predetermined area in the main RAM 65 is cleared. And, when the initialization is not executed, the power supply restoration command can be transmitted from the main CPU 63 to the sound emission control device 81.

FIG. 371 is a flowchart showing the command handling process executed by the CPU of the sound emission control device 81. The command response process is repeatedly executed by the CPU of the sound emission control device 81 in a relatively short cycle (for example, 4 milliseconds).

First, it is determined whether it is the management period after startup (step SP801). The post-startup management period is a period in which it is monitored whether or not a power-on command or a power restoration command is received from the main CPU 63 after the supply of operating power to the CPU of the sound emission control device 81 is started. The management period after startup is set to 5 seconds, but the specific period is arbitrary.

If it is in the management period after startup (step SP801: YES), it is determined whether or not a power-on command or a power recovery command has been received from the main CPU 63 (step SP802). When the power-on command or the power-return command is received (step SP802: YES), the management counter provided in the RAM of the voice emission control device 81 is cleared to “0” (step SP803). The management counter is a counter for measuring the management period after startup by the CPU of the voice light emission control device 81, and when it is started to be supplied with operating power to the CPU of the voice light emission control device 81, Numerical information corresponding to the management period is set.

After executing the processing of step SP803, when the power-on command is received this time, it is determined whether or not the setting change command is received together with the power-on command, and the power-return command is received this time. If so, it is determined whether or not the power supply restoration command and the setting confirmation command are received (step SP804). If an affirmative decision is made in step SP804, the command received this time among the power-on command and the power-restoring command is stored in the command storage area in the RAM of the sound emission control device 81 for reference in the subsequent processing (step SP805). ..

When a negative determination is made in step SP804, if the power supply return command has been received this time (step SP806: YES), the power supply return notification process is executed (step SP807), and the power-on command is received this time. If so (step SP806: NO), the RAM clear notification process is executed (step SP808). In the power recovery notification process, the display light emitting unit 53 and the display light emitting unit 53 are configured to perform the notification indicating that the power is recovered without executing “0” clearing and initialization of the predetermined area in the main RAM 65. While controlling the speaker unit 54, a command is transmitted to the display control device 82 so that the notification is executed by the symbol display device 41. The power restoration notification is continued for the power restoration notification period (for example, 5 seconds). In the RAM clear notification process, the display light emitting unit 53 and the display light emitting unit 53 are provided so that the notification indicating that the power is restored is executed in the state where “0” is cleared and initialized in the predetermined area in the main RAM 65. While controlling the speaker unit 54, a command is transmitted to the display control device 82 so that the notification is executed by the symbol display device 41. The RAM clear notification is continued for the RAM clear notification period (for example, 5 seconds).

When it is determined that neither the power-on command nor the power-return command is received in the management period after startup (step SP801: YES, step SP802: NO), the value of the management counter in the RAM of the sound emission control device 81 is set to 1 Subtract (step SP809). Then, when the value of the management counter after the subtraction of 1 becomes "0" (step SP810: YES), the management period after start-up is from the start of the supply of the operating power to the CPU of the sound emission control device 81. This means that neither the power-on command nor the power-restoring command has been received from the main CPU 63 until the time elapses. In this case, the communication abnormality notification processing is executed (step SP811).

In the communication abnormality notification process, the display light emitting unit 53 and the speaker unit 54 are controlled so that notification indicating that an abnormality has occurred in the signal path between the main CPU 63 and the sound emission control device 81 is executed. At the same time, the command is transmitted to the display control device 82 so that the notification is executed by the symbol display device 41. The communication abnormality notification is continued until the supply of operating power is stopped. When the communication abnormality notification is executed, another abnormality is executed before the communication abnormality notification is started because an abnormality has occurred in the signal path between the main CPU 63 and the sound emission control device 81. Not not.

In the command handling process, it is determined whether or not a setting change command has been received from the main CPU 63 (step SP812). When the setting change command is received (step SP812: YES), the setting change notification process is executed (step SP813). In the setting change notification process, the display light emitting unit 53 and the speaker unit 54 are controlled so that the notification indicating that the process for changing the setting value is being executed is executed, and the notification is displayed as a symbol. Send commands to the display controller 82 for execution by the device 41.

In the command handling process, it is determined whether or not a setting confirmation command has been received from the main CPU 63 (step SP814). When the setting confirmation command is received (step SP814: YES), the setting confirmation notification process is executed (step SP815). In the setting confirmation notification process, the display light emitting unit 53 and the speaker unit 54 are controlled so that the notification indicating that the process for confirming the set value is being executed is executed, and the notification is displayed as a symbol. Send commands to the display controller 82 for execution by the device 41.

In the command handling process, it is determined whether or not a setting end command has been received from the main CPU 63 (step SP816). When the setting end command is received (step SP816: YES), the setting related notification end processing is executed (step SP817). If the notification corresponding to the process for changing the setting value is being executed by the ending process of the setting related notification, the notification is ended and the process for confirming the setting value is supported. If the notification is performed, the notification ends.

After that, it is determined whether or not the power recovery command is stored in the command storage area in the RAM of the voice emission control device 81 (step SP818). When the power restoration command is stored (step SP818: YES), the notification that is the target of the termination this time is the notification corresponding to the process for confirming the set value, and the setting confirmation that triggered the notification is performed. When the command is received, it means that the power recovery command is also received. In this case, the power recovery notification process is executed (step SP819). The processing contents of the power recovery notification processing are the same as in step SP807. As a result, the power restoration notification is executed for the power restoration notification period (for example, 5 seconds).

When the power restoration command is not stored (step SP818: NO), the notification that is the target of the termination this time is a notification corresponding to the process for changing the setting value, and is for the setting change that triggered the notification. When the command is received, it means that the power-on command is also received. In this case, the RAM clear notification process is executed (step SP820). The processing contents of the RAM clear notification processing are the same as in step SP808. Thereby, the RAM clear notification is executed for the RAM clear notification period (for example, 5 seconds).

In the command corresponding process, other processes are executed in addition to the above various processes (step SP821). In other processes, for example, a process for executing the notification corresponding to the command transmitted in the payout state receiving process (step SP602) in the setting corresponding process (FIG. 367) of the main CPU 63 is executed. In addition to the above processing, when the main CPU 63 executes the main processing (FIG. 358) abnormal processing (step SN812) to transmit an abnormal command, a notification corresponding to the abnormal command is executed. Processing to ensure that. Further, in addition to the processing described above, processing for advancing the game is executed so that notification corresponding to the command transmitted from the main CPU 63 is executed.

Next, the manner in which a command is transmitted from the main CPU 63 to the sound emission control device 81 when the supply of operating power is started will be described with reference to the time chart in FIG. 372. 372(a) shows a period during which operating power is being supplied to the main CPU 63, and FIG. 372(b) shows processing at the start of supplying operating power (steps SN801 to SN821) in the main CPU 63. 372(c) shows the timing when the power-on command or the power restoration command is transmitted from the main CPU 63, and FIG. 372(d) shows the processing for changing the set value in the main CPU 63. 372 (e) shows the period during which the process for confirming the set value is being executed, FIG. 372(e) shows the timing at which the main CPU 63 sends the setting change command or the setting confirmation command, and FIG. 372(f). Indicates a period during which the CPU of the voice emission control device 81 measures the post-startup management period, and FIG. 372(g) indicates a period during which the communication abnormality notification is executed.

First, a case will be described in which communication between the main CPU 63 and the sound emission control device 81 is normally performed in a situation where the process for changing the set value and the process for confirming the set value are not executed.

At timing t1, supply of operating power to the main CPU 63 is started as shown in FIG. 372(a). In this case, at the timing of t1, the main CPU 63 starts the process (step SN801 to step SN821) at the time of starting the supply of the operating power, as shown in FIG. As shown in f), measurement of the management period is started after startup.

After that, at the timing of t2, as shown in FIG. 372(c), a power-on command or a power recovery command is transmitted from the main CPU 63, and the transmitted command is received by the voice emission control device 81. In this case, since the power-on command or the power recovery command is received by the voice emission control device 81 before the post-startup management period measured by the voice emission control device 81 has elapsed, the communication abnormality notification is executed. Not done.

Next, a case will be described in which communication between the main CPU 63 and the sound emission control device 81 is not normally performed in a situation where the process for changing the set value and the process for confirming the set value are not executed.

At timing t3, supply of operating power to the main CPU 63 is started as shown in FIG. 372(a). In this case, at the timing of t3, the main CPU 63 starts the process (step SN801 to step SN821) at the time of starting the supply of the operating power, as shown in FIG. As shown in f), the measurement of the management period is started after the startup.

After that, at the timing of t4, as shown in FIG. 372(c), the power-on command or the power recovery command is transmitted from the main CPU 63. However, since the abnormality has occurred in the signal path between the main CPU 63 and the sound emission control device 81, the command is not received by the sound emission control device 81.

After that, at the timing of t5, the post-startup management period measured by the sound emission control device 81 as shown in FIG. 372(f) elapses. In this case, since the voice emission control device 81 has not received the power-on command or the power-return command and the management period has elapsed after startup, communication abnormality notification is started as shown in FIG. 372(g). To be done.

Next, a case will be described in which communication between the main CPU 63 and the sound emission control device 81 is normally performed in a situation where the process for changing the set value or the process for confirming the set value is executed.

At timing t6, supply of operating power to the main CPU 63 is started as shown in FIG. 372(a). In this case, at the timing of t6, the main CPU 63 starts the process (step SN801 to step SN821) at the time of starting the supply of the operating power, as shown in FIG. As shown in f), measurement of the management period is started after startup.

After that, at the timing of t7, as shown in FIG. 372(d), the main CPU 63 starts the process for changing the set value or the process for confirming the set value. In this case, if the processing is to change the set value, the main CPU 63 sends a setting change command at the timing of t7 as shown in FIG. 372(e), and at the same time as shown in FIG. 372(c). A power-on command is transmitted from the side CPU 63. Further, in the case of the processing for confirming the set value, at the timing of t7, the main CPU 63 transmits the setting confirmation command as shown in FIG. 372(e) and the main side as shown in FIG. 372(c). A power return command is transmitted from the CPU 63. The power-on command or power-return command transmitted here is received by the voice emission control device 81. Therefore, at the timing of t7, the measurement of the post-startup management period in the sound emission control device 81 is finished as shown in FIG. 372(f).

Thereafter, at the timing of t8, the process for changing the set value or the process for confirming the set value is ended as shown in FIG. Steps SN801 to SN821) are ended.

<Process related to external output of security signal>
Next, a process for outputting a security signal from the main CPU 63 to the outside of the pachinko machine 10 (for example, a game hall management computer) will be described.

FIG. 373(a) is a flowchart showing security signal output start processing. The security signal output start process is performed when the first RAM clear process (step SN815) is executed in the main process (FIG. 358) based on the power being turned on while the RAM clear operation is performed. It is executed in step SN816 of the process (FIG. 358). Further, when the first RAM clearing process (step SN807) is executed when the process for changing the set value is started, the process is also executed in step SP504 of the setting process (FIG. 366) and the set value is set. Even when the second RAM clearing process (step SP517) of the setting process (FIG. 366) is executed when the process for changing the setting is finished, it is executed in step SP518 of the setting process (FIG. 366). It The processing from step SP901 to step SP902 in the security signal output start processing is executed by using the specific control program and specific control data in the main CPU 63.

First, information corresponding to the output continuation period (200 milliseconds) is set in the output continuation counter provided in the work area 221 for specific control in the main RAM 65 (step SP901). The output continuation counter is used by the main CPU 63 to specify whether or not the security signal is externally output and whether or not the period during which the security signal is externally output has reached the output continuation period. It is a counter.

After that, the output of the security signal is started (step SP902). As a result, external output of the security signal from the external terminal board of the pachinko machine 10 to the management computer of the game hall is started.

When the first RAM clear process (step SN815) is executed in the main process (FIG. 358) based on the power being turned on while the RAM clear operation is being performed as described above, the external output of the security signal is started. To be done. Further, when the first RAM clearing process (step SN807) is executed when the process for changing the set value is started, the external output of the security signal is started and the process for changing the set value is performed. Even when the second RAM clearing process (step SP517) is executed when is finished, the external output of the security signal is started. As a result, when the predetermined area of the main RAM 65 is cleared to "0" and initialized, it is possible to output the security signal to the outside for a period longer than the output continuation period. Therefore, it is possible for the management computer of the game hall to recognize that the predetermined area of the main RAM 65 has been cleared to "0" and initialized.

In the configuration in which the output start process of the security signal is executed in each of the case where the process for changing the setting value is started and the case where it is ended, when the process for changing the setting value is completed early, The security signal output start processing at the end of the processing for changing the setting value is executed in the situation where the external output of the security signal started at the start of the processing for changing the setting value is continued. Is assumed. In this case, in the security signal output start processing, regardless of whether the value of the output continuation counter is "0", that is, whether or not the output continuation period is being measured, the output continuation counter outputs continuously. A set of information corresponding to the time period is made. In other words, the security signal output start process at the end of the process for changing the set value was executed in the situation where the external output of the security signal started at the start of the process for changing the set value was continued. In this case, the output continuation period is reset in the situation where the external output of the security signal is continued. As a result, while reducing the processing load of the security signal output start processing, when a security signal output start timing occurs, the security signal output start timing is output regardless of whether or not the security signal is in the middle of external output. It is possible to externally output the security signal for the output continuation period from the timing at which the occurrence of the.

FIG. 373(b) is a flowchart showing security signal handling processing. The security signal handling process is executed in step SP407 of the first timer interrupt process (FIG. 365). The processing of steps SP911 to SP914 in the security signal handling processing is executed by using the program for specific control and the data for specific control in the main CPU 63.

When the value of the output continuation counter in the specific control work area 221 is 1 or more (step SP911: YES), 1 is subtracted from the value of the output continuation counter (step SP912). Then, when the value of the output continuation counter after the subtraction of 1 is "0" (step SP913: YES), the external output of the security signal is stopped (step SP914).

Next, how the security signal is output to the outside will be described with reference to the time chart in FIG. 374(a) shows a period during which operating power is being supplied to the main CPU 63, and FIG. 374(b) shows processing at the start of supplying operating power (step SN801 to step SN821) in the main CPU 63. 374(c) shows the timing when the first RAM clear processing or the second RAM clear processing is executed by the main CPU 63, and FIG. 374(d) changes the set value by the main CPU 63. 374(e) shows the timing at which the security signal output start processing is executed, and FIG. 374(f) shows the period during which the security signal is externally output.

First, the external output of the security signal is started when the first RAM clear process (step SN815) is executed in the main process (FIG. 358) based on the power being turned on while the RAM clear operation is performed. The case will be described.

At timing t1, supply of operating power to the main CPU 63 is started as shown in FIG. 374(a). In this case, at the timing of t1, the main CPU 63 starts the process (step SN801 to step SN821) at the start of supplying the operating power as shown in FIG. 374(b).

After that, at the timing of t2, the process at the start of supplying the operating power (step SN801 to step SN821) is ended as shown in FIG. 374(b), and the first RAM clearing process (step SN815) is executed. In this case, at the timing of t2, the security signal output start processing (FIG. 373(a)) is executed as shown in FIG. 374(e), so that the security signal is externally output as shown in FIG. 374(f). Is started. The external output of this security signal is performed over the output continuation period, and is ended at the timing of t3 as shown in FIG. 374(f).

Next, when the process for changing the setting value is executed based on the fact that the power is turned on in the state where the setting changing operation is performed, at the start of the process for changing the setting value, and A case will be described in which the security signal is individually output externally over the output continuation period at each end.

At timing t4, supply of operating power to the main CPU 63 is started as shown in FIG. 374(a). In this case, at the timing of t4, the main CPU 63 starts the process (step SN801 to step SN821) at the start of supplying the operating power as shown in FIG. 374(b).

After that, at the timing of t5, as shown in FIG. 374(d), the main CPU 63 starts the process for changing the setting value based on the fact that the power is turned on while the setting changing operation is performed. .. In this case, the first RAM clearing process (step SN807) is executed at the timing of t5 as shown in FIG. 374(c). Further, at the timing of t5, the security signal output start processing (FIG. 373(a)) is executed as shown in FIG. 374(e), so that the security signal is externally output as shown in FIG. 374(f). Be started. The external output of the security signal is performed for the continuous output period, and is ended at the timing of t6 as shown in FIG. 374(f).

After that, at the timing of t7, the processing for changing the set value is ended as shown in FIG. 374(d). In this case, the second RAM clearing process (step SP517) is executed at the timing of t7 as shown in FIG. 374(c). Further, at the timing of t7, the security signal output start processing (FIG. 373(a)) is executed as shown in FIG. 374(e), so that the security signal is externally output as shown in FIG. 374(f). Be started. The external output of this security signal is performed over the output continuation period, and is ended at the timing of t8 as shown in FIG. 374(f).

If the process for changing the set value continues for a period longer than the output duration of the security signal as described above, the external of the security signal started at the start of the process for changing the set value After the output is ended, the external output of the security signal at the end of the process for changing the set value is started. As a result, it becomes possible for the management computer of the game hall to grasp the execution timing of the RAM clearing process at the start and end of the process for changing the set value.

Next, when the process for changing the set value is executed based on the fact that the power is turned on while the setting change operation is performed, and at the time of starting the process for changing the set value. A case where the security signal output continuation period at the end is integrated with the security signal output continuation period will be described.

At timing t9, supply of operating power to the main CPU 63 is started as shown in FIG. 374(a). In this case, at the timing of t9, the main CPU 63 starts the process (step SN801 to step SN821) at the start of supplying the operating power as shown in FIG. 374(b).

Thereafter, at the timing of t10, as shown in FIG. 374(d), the main CPU 63 starts the process for changing the set value based on the fact that the power is turned on while the setting changing operation is performed. .. In this case, the first RAM clearing process (step SN807) is executed at the timing of t10 as shown in FIG. 374(c). Further, at the timing of t10, the security signal output start processing (FIG. 373(a)) is executed as shown in FIG. 374(e), so that the security signal is externally output as shown in FIG. 374(f). Be started.

Thereafter, the processing for changing the set value as shown in FIG. 374(d) is ended at the timing of t11, which is the situation where the external output of the security signal is continued. In this case, the second RAM clearing process (step SP517) is executed at the timing of t11 as shown in FIG. 374(c). Further, as shown in FIG. 374(e), the security signal output start processing (FIG. 373(a)) is executed at the timing of t11 to reset the security signal output continuation period. The external output of the security signal with the reset output duration is reset at the timing of t12 as shown in FIG. 374(f).

If the processing for changing the setting value ends in a shorter period than the security signal output duration as described above, the external output of the security signal started at the start of the processing for changing the setting value continues. The output continuation period is reset when the process for changing the setting value is completed in the situation where the output is continued. This makes it possible for the management computer in the game hall to recognize that the RAM clear processing has been executed at least once while reducing the processing load for outputting the security signal.

According to this embodiment described in detail above, the following excellent effects are exhibited.

In the main process (FIG. 358), the information corresponding to the state in which the supply of operating power is started is set in the determination register 651 of the main CPU 63, and the information set in the determination register 651 is used to execute the main processing. The type of processing to be executed in the processing (FIG. 358) is specified. This makes it possible to collectively specify the details of the state in which the supply of the operating power has been started, and to grasp the optimum process to be executed in the main process (FIG. 358) this time based on the specification result. ..

The determination register 651 is composed of a plurality of bits, and each of the plurality of bits has one of two values of “0” and “1” corresponding to the state where the supply of the operating power is started. Numerical information is set in. This makes it possible to reduce the processing load for collectively specifying the contents of the state in which the supply of operating power has been started.

The process to be executed in the main process (FIG. 358) is specified according to the judgment value specified based on the information set in each bit of the judgment register 651. Specifically, it is determined whether or not the process for changing the setting value is to be executed by determining whether or not the determination value is greater than or equal to the setting change reference value. Further, by determining whether or not the determination values are all “0”, it is determined whether or not the process for confirming the set value is in a situation to be executed. As a result, it is possible to grasp the optimum process to be executed in the main process (FIG. 358) of this time without individually specifying the numerical values stored in the plurality of bits of the judgment register 651. ..

Not only the process to be executed in the main process (FIG. 358) is specified according to the judgment value specified based on the information set in each bit of the judgment register 651, but also the predetermined bit of the judgment register 651 is determined. The process to be executed in the main process (FIG. 358) is specified depending on whether or not "1" is set in. As a result, the method for identifying the type of process to be executed in the main process (FIG. 358) this time is diversified, and it is possible to preferably identify the type of process to be executed.

When the supply of the operating power is started, it is determined whether or not the setting key insertion portion 68a is turned on by the setting key. If the setting key is turned on, the setting key flag (7th bit B7) of the determination register 651 is set. ) Is set to "1". Further, when supply of operating power is started, it is determined whether or not the reset button 68c is pressed, and when it is pressed, the reset button flag (6th bit B6) of the determination register 651 is set. "1" is set. When "1" is set in both the setting key flag (7th bit B7) and the reset button flag (6th bit B6), the processing for changing the setting value is executed, and the setting key flag ( If the value of 7-bit B7) is "0" and the reset button flag (6th bit B6) is set to "1", the first RAM clearing process (step SN815) is executed and the setting key flag (7th bit) is set. When "1" is set in the bit B7) and the value of the reset button flag (the sixth bit B6) is "0", the process for confirming the set value is executed. Thereby, when specifying whether to execute the process for changing the set value, when specifying whether to execute the first RAM clearing process (step SN815), and when confirming the set value, In each case of specifying whether or not to execute, it is not necessary to specify whether or not the setting key insertion portion 68a is turned on and whether or not the reset button 68c is pressed and operated, and the setting key insertion portion 68a is not necessary. It is only necessary to refer to the determination register 651 after once determining whether or not the ON operation has been performed and setting the information of the setting key flag (7th bit B7), and whether the reset button 68c is pressed. It is only necessary to refer to the determination register 651 after determining once or not and setting the information of the reset button flag (sixth bit B6). Therefore, the processing load can be reduced.

By using the determination register 651, execution of a process for changing a set value based on a setting change operation>setting of an abnormal state when an abnormality occurs>a process of changing a set value for a power interruption during setting change Resume> Execution of first RAM clear process based on RAM clear operation> Execution of process for confirming set value based on setting confirmation operation or resumption of process for confirming set value during power failure> Normal restoration It is possible to specify the process to be executed in the main process (FIG. 358) according to the priority of executing the power processing.

Both the information corresponding to the execution of the process having a relatively high priority among the above-mentioned processes and the information corresponding to the execution of the process having a relatively low priority among the above-mentioned processes are both registered in the judgment register. When set to 651, only the process with a relatively high priority is executed, and the process with a relatively low priority is not executed. This makes it possible to reduce the processing load of the main processing (FIG. 358).

Not only is the first RAM clear processing (step SN815) executed to clear a part of the area of the main RAM 65 to "0" when the RAM clear operation is occurring when the supply of the operating power is started. Even when the RAM clear operation is not performed when the supply of the operating power is started, the clear process at the time of turning on (step SN804) is executed, so that a partial area of the main side RAM 65 is set to “0”. It will be cleared. As a result, even when the RAM clear operation is not performed when the supply of the operating power is started, it is possible to set the state in which the information is not stored in the predetermined area of the main RAM 65.

In the power failure process (steps SN919 to SN924), the total value is calculated for all areas of the main RAM 65 including the checksum storage area 653, and the two's complement of the calculated total value is calculated, and the calculation is performed. The obtained 2's complement is stored in the checksum storage area 653. Further, in the abnormality determination process (FIG. 359), the total value is calculated for all areas of the main RAM 65, and if the calculated total value is not “0”, it means that a data abnormality has occurred in the main RAM 65. Specified. In this way, when the checksum is calculated, the total value of all areas of the main RAM 65 including the checksum storage area 653 is calculated, and thus the address range of the main RAM 65 that is the calculation target of the total value when the checksum is calculated. Need not be specified. Therefore, in the power failure process (steps SN919 to SN924) and the abnormality determination process (FIG. 359), the processing load for calculating the checksum can be reduced.

However, in the configuration in which the checksum is calculated as described above, the checksum storage area 653 immediately before the checksum is calculated in the power failure process (step SN919 to step SN924) is the data of all “0”. If not, the total value of all areas of the main RAM 65 calculated in step SN921 does not become the same as the total value of the other areas 654 in the main RAM 65, and accordingly, in step SN923. The 2's complement stored in the checksum storage area 653 is not the same as the 2's complement with respect to the total value of the other areas 654 in the main RAM 65. Then, in this situation, when the total value of all areas of the main RAM 65 is calculated, the total value does not become "0". The flag (fifth bit B5) is set to "1", and the abnormal state flag (fifth bit B15) of the state specifying area 652 is set to "1". On the other hand, a configuration may be considered in which all bits of the checksum storage area 653 are cleared to "0" when the power failure process (step SN919 to step SN924) is started. However, in this case, the processing load of the power outage process (steps SN919 to SN924) increases.

In such a situation, in the present embodiment, when the main process (FIG. 358) is started, and the abnormality determination process (FIG. 359) is performed after monitoring whether the checksum is normal or not is performed. Is executed (step SN804), all bits of the checksum storage area 653 of the main RAM 65 are cleared to "0", and the checksum storage area 653 becomes all "0" data. As a result, the processing load for calculating the checksum is reduced and the processing load of the power failure process (step SN919 to step SN924) is reduced, and the presence or absence of data abnormality in the main RAM 65 using the checksum is monitored. It becomes possible to do it appropriately.

Particularly, the clearing process at the time of insertion (step SN804) is a process for determining whether or not the abnormality process (step SN812) should be executed (step SN811), a process for changing the set value. Is executed before the process of starting (step SN807 to step SN810) and the process of starting the process for confirming the set value (step SN810, step SN818 to step SN819). As a result, the checksum storage area 653 can be set to all "0" data before the abnormality processing (step SN812), the processing for changing the setting value, and the processing for confirming the setting value are started. It will be possible. Since the abnormal process (step SN812), the process for changing the set value, and the process for confirming the set value are continued for a relatively long period, the probability of a power failure occurring in the middle of the process. Becomes higher. In this case, the checksum storage area 653 is set to all "0" data before these processes are started, so that the presence or absence of data abnormality in the main RAM 65 using the checksum is properly monitored. Is possible.

When the first RAM clear process (step SN815) is executed without executing the process for changing the set value and the process for confirming the set value when the supply of the operating power is started, the power is turned on. The command is transmitted to the voice emission control device 81. Further, when none of the process for changing the set value, the process for confirming the set value, and the first RAM clear process (step SN815) is performed when the supply of the operating power is started, the power is supplied. The return command is transmitted to the voice emission control device 81. Further, when the process for changing the set value is executed when the supply of the operating power is started, not only the setting change command but also the power-on command is transmitted in the setting process (FIG. 366). When the processing for confirming the set value is executed when the supply of the operating power is started, not only the setting confirmation command but also the power supply restoration command is transmitted in the setting processing (FIG. 366). That is, when the supply of operating power is started and the abnormal state is not set, either the power-on command or the power-return command is transmitted from the main CPU 63 to the sound emission control device 81. Become. When the voice emission control device 81 receives either the power-on command or the power-return command after the start-up management period has elapsed after the start of the supply of the operating power, the sound emission control device 81 does not execute the communication abnormality notification, while If neither the power-on command nor the power-restoration command is received before the start-up management period has elapsed after the start of supply, communication abnormality notification is executed. This makes it possible to monitor whether or not the signal path between the main CPU 63 and the sound emission control device 81 is normal when the supply of the operating power is started, and at the same time there is an abnormality in the signal path. If it occurs, it is possible to urge the manager of the game hall to deal with it.

When the process for changing the set value is executed when the supply of the operating power is started, not only the power-on command but also the setting change command is transmitted from the main CPU 63 to the sound emission control device 81. The sound emission control device 81 receives the power-on command to identify that no abnormality has occurred in the signal path with the main CPU 63. Further, the voice emission control device 81 receives the setting change command to notify that the process for changing the set value is being executed. By thus transmitting both the power-on command and the setting change command, it is possible to identify whether or not there is an abnormality in the signal path depending on whether or not the power-on command is received. When the process for changing the set value is executed, it is possible to execute the corresponding notification.

When the processing for confirming the set value is executed when the supply of the operating power is started, the main CPU 63 transmits not only the power restoration command but also the setting confirmation command to the sound emission control device 81. The voice emission control device 81 receives the power restoration command to identify that no abnormality has occurred in the signal path with the main CPU 63. Further, the voice emission control device 81 receives the setting confirmation command to notify that the process for confirming the set value is being executed. By thus transmitting both the power restoration command and the setting confirmation command, it is possible to identify whether or not there is an abnormality in the signal path depending on whether the power restoration command is received or not. When the process for confirming the set value is executed, it is possible to execute the corresponding notification.

When the first RAM clear process (step SN815) is executed without executing the process for changing the set value and the process for confirming the set value when the supply of the operating power is started, the power is turned on. In the configuration in which the command is transmitted to the voice emission control device 81, the power-on command is also transmitted to the voice emission control device 81 even when the process for changing the set value is executed. When the processing for changing the set value is executed, the first RAM clear processing (step SN807) and the second RAM clear processing (step SP517) are executed as described above. In this case, the power-on command is transmitted to the sound emission control device 81 even when the processing for changing the set value is executed, so that “0” of a predetermined area in the main RAM 65 is cleared. Also, when the initialization is executed, the power-on command can be transmitted from the main CPU 63 to the sound emission control device 81.

When the process for changing the set value, the process for confirming the set value, and the first RAM clear process (step SN815) are not executed when the supply of the operating power is started, the power restoration command is issued. Is transmitted to the voice emission control device 81, the power recovery command is also transmitted to the voice emission control device 81 when the process for confirming the set value is executed. When the process for confirming the set value is executed, neither the first RAM clear process nor the second RAM clear process is executed as described above. In this case, even when the process for confirming the set value is executed, the power restoration command is transmitted to the voice emission control device 81, so that “0” of the predetermined area in the main RAM 65 is cleared. And, when the initialization is not executed, the power supply restoration command can be transmitted from the main CPU 63 to the sound emission control device 81.

When the voice emission control device 81 receives both the power-on command and the setting change command, the sound emission control device 81 preferentially executes the notification corresponding to the process for changing the setting value, and ends the notification. After that, the notification corresponding to the power-on command is executed. As a result, when the processing for changing the set value is being executed, the notification corresponding to the processing is preferentially executed, while the notification corresponding to the power-on command is also executed individually. It becomes possible.

When the voice emission control device 81 receives both the power restoration command and the setting confirmation command, it gives priority to the notification corresponding to the fact that the processing for confirming the set value is being executed, and the notification ends. After that, the notification corresponding to the power restoration command is executed. As a result, when the process for confirming the set value is being executed, the notification corresponding to the setting value is preferentially executed, while the notification corresponding to the power restoration command is also executed individually. It becomes possible.

In order to execute not only the process (step SP409 to step SP421) for advancing the game in the first timer interrupt process (FIG. 365) that is activated periodically, but also the process regarding the set value (step SP603 to step SP610) The setting corresponding process (step SP406) is also executed. As a result, it becomes possible to regularly execute the process related to the set value in accordance with a predetermined cycle.

In the situation where the process related to the set value (step SP603 to step SP610) is executed in the first timer interrupt process (FIG. 365), "1" is set in the startup processing flag of the main RAM 65, The processing (step SP409 to step SP421) for advancing the game is not executed in the first timer interrupt processing (FIG. 365). This makes it possible to prevent the processing load of one first timer interrupt process (FIG. 365) from increasing.

Processing related to set values in the first timer interrupt processing (FIG. 365) based on execution of interrupt permission processing (step SP511) in the setting processing (FIG. 366) executed in the main processing (FIG. 358) (Steps SP603 to SP610) are executed. As a result, in order to execute the process related to the set value (steps SP603 to SP610), it is necessary to temporarily stop the supply of the operating power and then start the supply of the operating power. It is possible to make it difficult to execute (step SP603 to step SP610) illegally.

When the setting process (FIG. 366) executed in the main process (FIG. 358) becomes the state in which the interrupt permission process (step SP511) is executed, the setting key insertion unit 68a is changed from the ON state to the OFF state. The setting process (FIG. 366) is not completed until it is specified that the setting has been switched to. Then, the process for advancing the game (step SP409 to step SP421) is not executed until the setting process (FIG. 366) is completed. Thereby, it is possible to prevent the process (step SP409 to step SP421) for advancing the game from being executed in a situation where the process related to the set value (step SP603 to step SP610) can be executed.

Even in the situation where the process (step SP603 to step SP610) related to the set value is executed in the first timer interrupt process (FIG. 365), the payout state receiving process (step SP602) is executed in the first timer interrupt process (FIG. 365). ) Is executed. As a result, it is possible to monitor whether or not various situations have occurred even in the situation where the process related to the set value (steps SP603 to SP610) is being executed.

The external output of the security signal is started when the first RAM clear process (step SN815) is executed in the main process (FIG. 358) based on the fact that the power is turned on while the RAM clear operation is performed. Further, when the first RAM clearing process (step SN807) is executed when the process for changing the set value is started, the external output of the security signal is started and the process for changing the set value is performed. Even when the second RAM clearing process (step SP517) is executed when is finished, the external output of the security signal is started. As a result, when the predetermined area of the main RAM 65 is cleared to "0" and initialized, it is possible to output the security signal to the outside for a period longer than the output continuation period. Therefore, it is possible for the management computer of the game hall to recognize that the predetermined area of the main RAM 65 has been cleared to "0" and initialized.

If the process for changing the set value continues for a period longer than the output duration of the security signal, the external output of the security signal started at the start of the process for changing the set value ends. After that, the external output of the security signal at the end of the process for changing the set value is started. As a result, it becomes possible for the management computer of the game hall to grasp the execution timing of the RAM clearing process at the start and end of the process for changing the set value.

In the configuration in which the output start process of the security signal is executed in each of the case where the process for changing the setting value is started and the case where it is ended, when the process for changing the setting value is completed early, The security signal output start processing at the end of the processing for changing the setting value is executed in the situation where the external output of the security signal started at the start of the processing for changing the setting value is continued. Is assumed. In this case, in the security signal output start processing, regardless of whether the value of the output continuation counter is "0", that is, whether or not the output continuation period is being measured, the output continuation counter outputs continuously. A set of information corresponding to the time period is made. In other words, the security signal output start process at the end of the process for changing the set value was executed in the situation where the external output of the security signal started at the start of the process for changing the set value was continued. In this case, the output continuation period is reset in the situation where the external output of the security signal is continued. As a result, while reducing the processing load of the security signal output start processing, when a security signal output start timing occurs, the security signal output start timing is output regardless of whether or not the security signal is in the middle of external output. It is possible to externally output the security signal for the output continuation period from the timing at which the occurrence of the.

When the power is turned on while the setting change operation is performed, even if the data abnormality in the main RAM 65 is specified in the main process (FIG. 358) started when the power is turned on, the abnormal state is detected. The process for changing the setting value is started without being set to. When the process for changing the set value is executed, the main RAM 65 is cleared to "0" and initialized, and the set value is newly set. In such a situation, by prioritizing the start of the processing for changing the set value over the setting of the abnormal state, it is possible to eliminate the data abnormality of the main side RAM 65 without requiring the power OFF/ON operation again. Is possible.

If the execution of the process for changing the setting value has priority over the setting for the abnormal state, the process for advancing the game without setting the abnormal state after the process for changing the setting value is completed (Steps SP409 to SP421) are started. This makes it possible to smoothly start the process for advancing the game (steps SP409 to SP421) in a configuration in which execution of the process for changing the set value is prioritized.

The first RAM clearing process (step SN807) is executed when the process for changing the set value is started, and the second RAM clearing process (step SP517) is executed when the process for changing the set value is finished. In the configuration described above, even if the first RAM clearing process (step SN807) is executed, the abnormal state flag (fifth bit B15) of the state specifying area 652 is not cleared to "0", whereas the second RAM clearing process ( When step SP517) is executed, the abnormal state flag (fifth bit B15) is cleared to "0". This prevents an abnormal state from being set after the process for changing the set value, but if the supply of operating power is stopped during the process for changing the set value, the subsequent operation is performed. It becomes possible that the abnormal state flag (the fifth bit B15) is set to "1" when the power supply is started.

Even if the power is turned on while the setting change operation is not being performed, if the previous power off occurred during the process for changing the set value, the set value is changed. In the configuration in which the processing of FIG. 3 can be restarted, even if the previous power-off occurs in the middle of the processing for changing the set value, the main processing (FIG. 358) triggered by the power-on of this time is used. When the occurrence of the data abnormality in the RAM 65 is specified, the process for changing the set value is not prioritized but is set to the abnormal state. This makes it possible to limit the process prioritized over the setting of the abnormal state to the process for changing the set value when the power is turned on while the setting change operation is performed.

The role of the flag assigned to each bit of the determination register 651 may be different from that of the above embodiment. For example, the configuration may be such that the seventh bit B7 of the determination register 651 is assigned as the reset button flag and the sixth bit B6 of the determination register 651 is assigned as the setting key flag. Further, the seventh bit B7 of the determination register 651 is assigned as an abnormality flag, the sixth bit B6 of the determination register 651 is assigned as a power interruption flag during setting change, and the fifth bit of the determination register 651 is assigned. B5 is assigned as the setting confirmation power failure flag, the fourth bit B4 of the determination register 651 is assigned as the setting key flag, and the third bit B3 of the determination register 651 is assigned as the reset button flag. It may be configured. In this case, the setting key flag (4th bit B4) and the reset button flag (3rd bit) are used when determining whether or not the processing for changing the setting value based on the setting change operation should be executed. It may be determined whether or not "1" is set in both of B3).

Further, the configuration register 651 may have a configuration in which neither the setting change power failure flag nor the setting confirmation power failure flag is set. In this case, the main process (FIG. 358) determines whether or not the setting change state flag (7th bit B17) of the state specifying area 652 is set to "1", thereby supplying the previous operating power. It may be configured to specify whether or not the process for changing the set value was being executed when the process was stopped. In addition, by specifying whether or not "1" is set in the setting confirmation status flag (sixth bit B16) of the status specification area 652 in the main processing (FIG. 358), it is possible to supply the previous operating power. It may be configured to specify whether or not the process for confirming the set value is being executed when the process is stopped.

Further, a plurality of bits of the determination register 651 may be allocated as an area for specifying whether or not the situation is predetermined. For example, instead of the abnormality flag, an abnormal area consisting of 2 bits may be set, and two types of abnormalities for which numerical values are set in the abnormal area may be set. In this case, when a device failure such as a failure of the payout device 76 occurs, numerical information of "10" is set in the 2-bit abnormal area, and when a data error of the main side RAM 65 occurs, 2 is set. Numerical information "01" is set in the abnormal area of the bit. When the numerical information of "10" is set in the abnormal area, the abnormal state is set even when the setting change operation is performed. In this case, an abnormality confirmation button is provided in the main control device 60 in addition to the setting key insertion portion 68a and the reset button 68c, and the abnormality state is released when the abnormality confirmation button is pressed in addition to the setting change operation. May be configured. Further, when the numerical information of “01” is set in the abnormal area, if the setting change operation is being performed, the execution of the process for changing the setting value is prioritized, while the setting change operation is performed. If not, the configuration is set to an abnormal state. Thereby, it becomes possible to specify the abnormality of the pachinko machine 10 in a plurality of stages, and it is possible to execute the process according to the stage identified as the abnormality in the main process (FIG. 358). Become.

The order in which the clearing process (step SN804) at the time of insertion in the main process (FIG. 358) is performed is not limited to the configuration after the state setting process (step SN803) for the determination register 651. For example, the configuration may be performed after the abnormality determination process (step SN802) and before the state setting process (step SN803) for the determination register 651. In this case, the checksum storage area 653 is cleared to "0" immediately after it is specified whether or not a data abnormality has occurred in the main RAM 65. Further, the clear processing at the time of insertion (step SN804) may be executed after the operation determination processing (step SN805) but before step SN806. Even in this case, the checksum storage area 653 can be cleared to “0” before the processing for changing the setting value and the processing for confirming the setting value are started.

Further, in the above embodiment, the total value of all areas in the main RAM 65 is calculated as a checksum in the power failure information storage process (FIG. 361), the two's complement of the total value is calculated, and the calculated result is stored in the checksum. Although the configuration is such that it is stored in the area 653, it is not limited to this. For example, in the power failure information storage processing (FIG. 361), the total value of all areas in the main RAM 65 is calculated, and the calculated result is stored in the checksum storage area 653. In the abnormality determination processing (FIG. 359), the main RAM 65 of the main RAM 65 is stored. A configuration may be adopted in which the total value of areas other than the checksum storage area 653 is calculated and whether the calculated total value is the same as the numerical value stored in the checksum storage area 653. Even with this configuration, the power failure information storage processing (FIG. 361) is executed by clearing the checksum storage area 653 to “0” in the clear processing (step SN804) at the time of insertion in the main processing (FIG. 358). In this case, it is possible to specify whether or not a data abnormality has occurred in the main RAM 65 without executing "0" clear of the checksum storage area 653.

Further, the area of the main side RAM 65 that is the target of clearing “0” in the clear processing at the time of insertion (step SN804) in the main processing (FIG. 358) is not limited to the checksum storage area 653. For example, in the clear processing at the time of insertion (step SN804), in addition to or instead of the checksum storage area 653, an area referred to by the main CPU 63 for specifying whether or not the gaming machine main body 12 is in an open state. May be cleared to "0", and the area referred to for specifying whether or not the front door frame 14 is in the open state may be cleared to "0". The area in which the display data of the first to fourth notification display devices 201 to 204 is stored may be cleared to "0".

Two types of commands, a power-on command and a power recovery command, are used as commands for identifying whether or not an abnormality has occurred in the signal path between the main CPU 63 and the sound emission control device 81. Although the configuration has been described, the present invention is not limited to this. For example, one type of communication confirmation command may be used. In this case, when the process for changing the set value is executed, the communication confirmation command and the setting change command are transmitted from the main CPU 63 to the sound emission control device 81, and the process for confirming the set value is executed. When executed, the communication confirmation command and the setting confirmation command are transmitted from the main CPU 63 to the voice emission control device 81, and both the process for changing the set value and the process for confirming the set value are performed. If neither executed nor set to the abnormal state, the communication confirmation command is transmitted from the main CPU 63 to the voice emission control device 81 regardless of whether the first RAM clear process (step SN815) is executed. According to this configuration, it is possible to reduce the types of commands.

Further, when the voice emission control device 81 receives both the setting change command and the power-on command, it executes the notification corresponding to the process for changing the setting value and then executes the notification corresponding to the power-on command. However, the present invention is not limited to this, and may be configured such that the notification corresponding to the processing for changing the set value is executed and the notification corresponding to the power-on command is not executed. Further, the configuration may be such that the notification corresponding to the processing for changing the set value and the notification corresponding to the power-on command are executed alternately.

Further, when the voice emission control device 81 receives both the setting confirmation command and the power restoration command, it executes a notification corresponding to the processing for confirming the set value and then executes a notification corresponding to the power restoration command. However, the present invention is not limited to this, and the configuration may be such that the notification corresponding to the processing for confirming the set value is executed and the notification corresponding to the power restoration command is not executed. Further, the configuration may be such that the notification corresponding to the process for confirming the set value and the notification corresponding to the power restoration command are executed alternately.

In addition, a process for specifying whether or not the setting key insertion unit 68a has been switched from the ON state to the OFF state in the configuration in which the setting correspondence process (FIG. 367) is executed in the first timer interrupt process (FIG. 365) ( Step SP513) is configured to be executed in the main process (FIG. 358), but is not limited to this, and is for specifying whether or not the setting key insertion portion 68a has been switched from the ON state to the OFF state. The processing (step SP513) may be configured to be executed by the setting corresponding processing (FIG. 367). Even in this case, the setup processing flag is cleared to "0" when it is specified in the setting correspondence processing (FIG. 367) that the setting key insertion unit 68a is switched from the ON state to the OFF state. By doing so, the process for advancing the game (step SP409 to step SP421) should not be executed in the situation where the process for changing the setting value or the process for confirming the setting value is being executed. Is possible.

Also, which of the process for changing the set value and the process for confirming the set value should be started in the configuration in which the setting corresponding process (FIG. 367) is executed in the first timer interrupt process (FIG. 365). The processing for specifying whether or not it may be executed by the first timer interrupt processing (FIG. 365) instead of the main processing (FIG. 358).

Further, the setting process (FIG. 367) executed in the first timer interrupt process (FIG. 365) is not limited to the configuration in which the payout state receiving process (step SP602) is executed, and the main process (FIG. 358) is executed. ), the payout state receiving process (step SP602) may be executed in the setting process (FIG. 366). Specifically, the payout state receiving process (step SP602) is executed after step SP510 and before step SP511 in the setting process (FIG. 366), and the setting key insertion unit 68a is turned on in step SP513. When it is determined that the state has not been switched to the OFF state, the process may return to the payout state receiving process (step SP602). Even with such a configuration, the state of the pachinko machine 10 can be monitored even in the situation where the process for changing the set value or the process for confirming the set value is being executed.

Further, when the occurrence of an abnormality in the payout device 76 or the occurrence of a predetermined fraud is specified in the payout state receiving process (step SP602) in the setting corresponding process (FIG. 367), the process or setting for changing the setting value is performed. The configuration may be such that the abnormality notification is executed and the subsequent process is stopped even while the process for confirming the value is being executed. As a result, it becomes possible to promptly deal with the occurrence of an abnormality even while the process for changing the set value or the process for confirming the set value is being executed.

Further, the payout state receiving process (step SP602) is not set in the setting corresponding process (FIG. 367), but the payout state is a process from step SP401 to step SP408 in the first timer interrupt process (FIG. 365). The reception process (step SP602) may be set. In this case, the payout state receiving process (step SP602) is executed regardless of whether the process for changing the set value or the process for confirming the set value is in the middle of execution. In the first timer interrupt process (FIG. 365), the payout state reception process of step SP418 is unnecessary.

Further, when a new output start trigger of the security signal occurs in the situation where the security signal is being output to the outside, the output continuation counter of the main RAM 65 is not reset but the output continuation period information is reset. The fixed value may be uniformly added to the numerical value stored in the output continuation counter. In this case, the output continuation period is not reset and the output continuation period is extended by a fixed value. In addition, the information of the output duration may be added as the fixed value. In this case, when a new output start trigger of the security signal occurs in the situation where the security signal is externally output, the total period during which the security signal is externally output becomes twice the output continuation period. ..

In addition, when a new output start trigger for the signal occurs while the signal is being output externally, a configuration that extends the output continuation period of the signal is provided for external output of signals other than the security signal. You may apply.

Further, in the case where the supply of the operating power is stopped during the execution of the process for changing the set value and the setting change operation is not performed when the supply of the operating power is started after that, When the occurrence of a data abnormality in the main RAM 65 is specified, in the above-described embodiment, the abnormal state is set without executing the process for changing the set value, but the configuration is limited to this. Alternatively, the configuration for changing the set value may be prioritized and the abnormal state may not be set.

Further, the voice emission control device 81 transmits by the payout state receiving process (step SP602) of the setting corresponding process (FIG. 367) from the reception of the setting change command or the setting confirmation command until the reception of the setting end command. When any one of the commands is received, the received command is temporarily stored, and after the setting end command is received and the notification corresponding to the setting-related processing is ended, it is transmitted in the payout state reception processing. The configuration may be such that the notification corresponding to the issued command is started. More specifically, it corresponds to the processing for changing the setting value when any command is transmitted in the payout state receiving processing in the situation where the processing for changing the setting value is being executed. The notification corresponding to the command transmitted in the payout state reception process may be executed after the notification ends and the notification corresponding to the power-on command ends. Also, in the situation where the process for confirming the set value is being executed, if any command is transmitted in the payout state reception process, the notification corresponding to the process for confirming the set value ends. Further, the notification corresponding to the command transmitted in the payout state reception process may be executed after the notification corresponding to the power restoration command is completed. This makes it possible to prevent other notifications from being executed while the notification corresponding to the setting-related processing is being executed, and it is also possible to ensure execution of the other notifications. ..

Further, in the first RAM clearing process (steps SN807 and SN815) and the second RAM clearing process (step SP517), the predetermined area of the main side RAM 65 is cleared to "0" and initialized, but is not limited to this. However, the configuration may be such that "0" is cleared but initialization is not executed.

In addition, if the supply of operating power is stopped during the process of changing the set value and the process for changing the set value is restarted at the start of the subsequent supply of the operating power, Although the security signal output start processing (FIG. 373(a)) is configured to be executed at the time of start, the present invention is not limited to this, and in the above-described situation, at the start of processing for changing the set value. The security signal output start processing (FIG. 373(a)) may not be executed. Specifically, the security signal output start process is not executed in step SP504 of the setting process (FIG. 366), but the security process is performed after step SN807 and before step SN808 in the main process (FIG. 358). The configuration is such that signal output start processing is executed.

Further, when the process for changing the set value is executed, all areas of the main RAM 65 may be cleared to "0" at the start thereof. Further, when the processing for changing the set value is executed, all the areas of the specific control work area 221 and the specific control stack area 222 in the main RAM 65 are cleared to "0" at the start thereof, The work area 223 for non-specific control and the stack area 224 for non-specific control may not be cleared to "0".

<Other Embodiments>
It should be noted that the present invention is not limited to the description of the above-described embodiment, and various modifications and improvements can be made without departing from the spirit of the present invention. For example, you may change as follows. By the way, the configurations of the following different modes may be applied to the configurations of the above-described embodiments individually or in combination.

(1) In the first to fourteenth embodiments described above, the number of times the open/close execution mode is generated per unit game is calculated as a parameter indicating the frequency of occurrence of the open/close execution mode. The number of times the open/close execution mode is generated may be divided by the total number of game balls discharged from the game area PA to calculate the result. In addition to or instead of this, a configuration is calculated in which the number of times the open/close execution mode is generated is divided by the total number of balls entering the first operation port 33 and the number of balls entering the second operation port 34. May be Moreover, you may apply the said structure to the said 15th-97th embodiment.

(2) In the first to fourteenth embodiments, as a parameter indicating the occurrence frequency of the high-frequency support mode, the high-frequency support mode for the number of times of the high-frequency support mode and the number of times of opening/closing execution mode per unit game time However, in addition to or instead of this, the result obtained by dividing the number of occurrences of the high frequency support mode by the total number of discharged game balls from the game area PA may be calculated. Good. In addition to or instead of this, the result of dividing the number of occurrences of the high frequency support mode by the total number of balls entering the first operation port 33 and the number of balls entering the second operation port 34 is calculated. It may be configured. Moreover, you may apply the said structure to the said 15th-97th embodiment.

(3) As a game result that triggers the opening and closing execution mode, not only a big hit result but also a small hit result may be present. When the small hit result is obtained, the open/close execution mode is generated, but the win/loss lottery mode and the support mode are not changed before and after the open/close execution mode. Further, the opening/closing execution mode that results in a small hit may be configured to be a low frequency winning mode. In this case, when the big hit result occurs, history information corresponding to the occurrence of the big hit result is stored in the history memory 117, and when the small hit result occurs, the history information corresponding to the occurrence of the small hit result is the history. It may be configured to be stored in the memory 117 for use. Further, in this configuration, the history information stored in the history memory 117 may be used to calculate the parameter indicating the frequency of occurrence of the big hit result and the parameter indicating the frequency of occurrence of the small hit result. Moreover, you may apply the said structure to the said 15th-97th embodiment.

Further, the probability of winning the small hit result may be changed according to the setting state of the pachinko machine 10, or may be unchanged. In the case of a configuration in which the probability of winning the small hit result changes according to the setting state of the pachinko machine 10, the higher the set value, the higher the probability of winning the small hit result may be. It may be configured to have a low probability of performing.

In addition, in the configuration in which the small hit result exists, the holding information acquired when the game ball enters the first operating port 33 and the holding information acquired when the game ball enters the second operating port 34. When the jackpot result and the jackpot result are different from each other, the distribution ratios of the jackpot results are different, and when aiming to enter the first working opening 33, the variable display unit 36 is used in the game area PA. Also, the shooting operation is performed so that the game ball flows down the left side area, and when aiming to enter the second working opening 34, the game ball flows down the area on the right side of the variable display unit 36 in the game area PA. The shooting operation may be performed as described above, and the small hit result may be generated based on the hold information acquired when the game ball enters the first operating port 33.

In the configuration, the following 51st parameter may be present as a result of managing the game history. It should be noted that the normal period is the sum of the execution period of the opening/closing execution mode triggered by the small hit result based on the ball entering the first operation port 33 and the execution period of the low frequency support mode instead of the opening/closing execution mode. To do. Further, the number of balls entered into the outlet 24a during the normal period is the number of balls entered K51, and the number of balls entered into the general prize hole 31 during the period of normal is the number K52 of balls entered. The number of balls entered is K53, the number of balls entered into the first operation port 33 during the normal period is the number of balls entered K54, and the number of balls entered into the second operation port 34 during the normal period is the number of balls entered K55.
The 51st parameter: the total payout number of game balls in the normal period (K52 x "the number of prize balls for winning the general prize hole 31" + K53 x "the number of prize balls for winning the special electric prize winning device 32" + K54 x "first" Ratio of the total number of game balls (K51+K52+K53+K54+K55) discharged from the game area PA in the normal period)+K55דnumber of prize balls for winning in the second operation port 34”)/K55 In the configuration in which the 51st parameter is calculated, when the winning probability of the small hit result varies depending on the setting state of the pachinko machine 10, the normal value of the 51st parameter varies depending on the setting state of the pachinko machine 10. Becomes Therefore, it is preferable that the history information used for calculating the 51st parameter is deleted when the setting state of the pachinko machine 10 is changed. On the other hand, if the winning probability of the small hit result does not change according to the setting state of the pachinko machine 10, the normal value of the 51st parameter does not change according to the setting state of the pachinko machine 10. Therefore, it is preferable that the history information used for calculating the 51st parameter is not deleted even if the setting state of the pachinko machine 10 is changed.

(4) In the first to fourteenth embodiments described above, the history information corresponding to the occurrence of the opening/closing execution mode may be stored in the history memory 117 regardless of which kind of jackpot result occurs. Thus, history information corresponding to the type of jackpot result may be stored in the history memory 117. In this case, a parameter indicating the frequency of occurrence may be calculated for each type of jackpot result. Moreover, you may apply the said structure to the said 15th-97th embodiment.

(5) In the first to fourteenth embodiments, various parameters (first to eighth parameters, eleventh to eighteenth parameters, twenty-first to twenty-sixth parameters, thirty-first parameters, and thirty-first to fourty-second parameters are periodically provided. However, the present invention is not limited to this, and various parameters are calculated, for example, when the total number of game balls discharged from the game area PA reaches the calculation trigger number (for example, 10,000). The configuration may be such that various parameters are calculated when the supply of operating power to the pachinko machine 10 is stopped, and the number of game times executed is the number of calculation triggers (for example, 1000 times). In this case, various parameters may be calculated. In this case, the history memory 117 may be cleared to "0" at the timing when various parameters are calculated. Moreover, you may apply the said structure to the said 15th-97th embodiment.

(6) In the first to fourteenth embodiments described above, the first to eighth parameters, the eleventh to eighteenth parameters, the twenty-first to twenty-sixth parameters, the thirty-first parameters, the thirty-first parameters, and the thirty-first parameters each time the calculation timing of various parameters comes. Although all of the 41st to 42nd parameters are calculated, the present invention is not limited to this, and only one part of the various parameters described above is the calculation target at one calculation timing, and the calculation timing is changed every time. The parameter groups to be calculated may be sequentially changed. For example, the first to eighth parameters are calculated at one calculation timing, the first to eighteenth parameters are calculated at the next calculation timing, the second to twenty-sixth parameters are calculated at the next calculation timing, and the next calculation is performed. The 31st parameter and the 41st to 42nd parameters may be calculated at the timing, and thereafter, the calculation object may be repeatedly changed in the above order each time the calculation timing comes. As a result, it is possible to reduce the processing load for calculating the parameter when one calculation timing is reached. Moreover, you may apply the said structure to the said 15th-97th embodiment.

(7) In the above-described first to fourteenth embodiments, various parameters may be calculated using the history information of the history memory 117 on condition that a game is being played. For example, the calculation of various parameters may be performed on condition that the game ball is supplied to the game area PA. This makes it possible to prevent the calculation of various parameters from being unnecessarily repeated even when a game is not being played. Moreover, you may apply the said structure to the said 15th-97th embodiment.

(8) The first to fourteenth embodiments are not limited to the configuration in which the management IC 66 is provided separately from the main CPU 63, and the function of the management IC 66 is performed by the main CPU 63. It may be configured. In this case, the correspondence information is stored in the main ROM 64 in advance. Further, the history memory 117, the calculation result memory 131, and the separate storage memory 171 may be provided separately from the main RAM 65. In the main RAM 65, the history memory 117, the calculation result memory 131, and the separate storage memory 171 may be provided. The configuration may be such that the function of the storage memory 171 is fulfilled. In the configuration in which the functions of the history memory 117, the operation result memory 131, and the separate storage memory 171 are fulfilled in the main RAM 65, the history data is recorded when the main RAM 65 clear processing (step S105, step S117) is executed. A part or all of the area corresponding to each of the memory 117, the operation result memory 131, and the separate storage memory 171 may be cleared to “0”, and the history memory 117, the operation result memory 131, and the separate storage. Areas corresponding to the respective memory 171 may be excluded from the target of “0” clear, and “0” may be cleared when the corresponding clear condition in each of the above embodiments is satisfied. Further, in the main side RAM 65, the manual operation contents for executing the clear processing may be different between the areas corresponding to the history memory 117, the calculation result memory 131 and the separate storage memory 171 and the other areas. Good. The function of the management IC 66 may be fulfilled by the sound emission control device 81.

(9) In the first to fourteenth embodiments, when a new setting of the setting state of the pachinko machine 10 is performed, the history information in the history memory 117 is stored and held without being erased, and the calculation is performed. The configuration may be such that various parameters stored in the result memory 131 are deleted. This makes it possible to prevent notification of the various parameters calculated before the setting is performed after the new setting of the setting state is performed. Moreover, you may apply the said structure to the said 15th-97th embodiment.

(10) In the third to fifth embodiments, even if a new setting of the setting state of the pachinko machine 10 is performed (that is, even if the main CPU 63 executes the setting value update process), If the set value is not changed before and after the setting, the history memory 117 may not be cleared. As a result, it is possible to prevent the history information in the history memory 117 from being erased even though the set value has not been changed.

In this configuration, the area for storing the set value in the main RAM 65 is excluded from the target of clearing "0" even if the clearing process (step S117) is executed, whereby the set value updating process ( It becomes possible for the main CPU 63 to specify whether or not the set value has been changed before and after step S118). In this case, when the main CPU 63 specifies that the setting value has not been changed, the management CPU 112 outputs a signal to the management CPU 112 so that the setting update recognition process is not executed, and the main CPU 63 When it is specified that the setting value has been changed in, the management side CPU 112 may output a signal to the management side CPU 112 so that the setting update recognition process is executed.

Further, when the signal indicating that the setting state of the pachinko machine 10 is newly set is received from the main CPU 63, the management CPU 112 refers to the history information stored in the history memory 117. It may be configured to specify whether or not the set value has been changed. In this case, when the management CPU 112 specifies that the setting value has not been changed, the clearing process of the history memory 117 is not executed, and the management CPU 112 specifies that the setting value has been changed. In this case, it is possible to execute the clearing process of the history memory 117.

(11) In the third to fifth embodiments, even if a new setting of the setting state of the pachinko machine 10 is performed (that is, even if the main CPU 63 executes the set value updating process), When the setting value is not changed before and after the setting, the arithmetic processing of various parameters triggered by the new setting of the setting state may not be executed. As a result, it is possible to prevent the various parameters from being calculated when the setting value is newly set, even though the setting value has not been changed.

In this configuration, the area for storing the set value in the main RAM 65 is excluded from the target of clearing "0" even if the clearing process (step S117) is executed, whereby the set value updating process ( It becomes possible for the main CPU 63 to specify whether or not the set value has been changed before and after step S118). In this case, when the main CPU 63 specifies that the setting value has not been changed, the management CPU 112 outputs a signal to the management CPU 112 so that the setting update recognition process is not executed, and the main CPU 63 When it is specified that the setting value has been changed in, the management side CPU 112 may output a signal to the management side CPU 112 so that the setting update recognition process is executed.

Further, when the signal indicating that the setting state of the pachinko machine 10 is newly set is received from the main CPU 63, the management CPU 112 refers to the history information stored in the history memory 117. It may be configured to specify whether or not the set value has been changed. In this case, when it is determined that the setting value has not been changed by the management CPU 112, calculation of various parameters triggered by the new setting of the current setting state is not executed, and the setting is performed by the management CPU 112. When it is specified that the value has been changed, it is possible to execute the calculation of various parameters triggered by the new setting of the current setting state.

(12) In the third to fifth embodiments, when a new setting of the setting state of the pachinko machine 10 is performed, various parameters may be calculated by various calculation processes (step S1807) at that time. Instead, the various parameters stored in the operation result memory 131 at that time are stored in the storage target area of the first to fifth separate storage areas 172 to 176 of the separate storage memory 171, and the calculation is performed. The information stored in the result memory 131 may be cleared to “0”. In this case, since it is not necessary to calculate various parameters under the situation where the setting state of the pachinko machine 10 is newly set, it is possible to complete the storage of various parameters in the separate storage memory 171 at an early stage. Become.

(13) In the third to fifth embodiments, the contents of various parameters stored in the first to fifth separate storage areas 172 to 176 of the separate storage memory 171 are changed by performing a predetermined display start operation. It may be configured to be displayed on the first to third notification display devices 69a to 69c or another display device. The predetermined display start operation may be performed by operating a dedicated operation unit, or may be performed by performing a predetermined dedicated operation on an operation unit for performing another operation. This makes it possible to easily confirm various parameters stored in the separate storage memory 171.

(14) All of the outlet 24a, the general winning opening 31, the special electric winning device 32, the first operating opening 33, and the second operating opening 34 are set as the storage targets of the history information (or the entry history). However, the present invention is not limited to this, and only a part of the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first working opening 33, and the second working opening 34 is the storage target of the history information. May be For example, the general winning opening 31, the special electric winning device 32, and the second operating opening 34 may be the target of storing history information, or the general winning opening 31 may be the target of storing history information. It’s good. Even in this case, it is possible to grasp the entering mode of the game ball in a predetermined period for the entering part for which the history information is stored.

(15) A signal path for transmitting information corresponding to the result of entering a game ball in association with each of the first winning opening detection sensor 42a, the second winning opening detection sensor 43a, and the third winning opening detection sensor 44a. Although the configuration in which 118a to 118c are set is not limited to this, the information corresponding to the ball entry result for the same type of ball entry portion includes a plurality of the same type of ball entry portions. In addition to the configuration in which there are a plurality of ball entrance detection sensors in accordance with that, it may be configured to be transmitted as one type of information. This makes it possible to reduce the number of types of information transmitted from the main CPU 63 to the management IC 66.

(16) In the above-described first to fourteenth embodiments, the correspondence information indicating the correspondence between the types of information transmitted from the main CPU 63 to the management IC 66 and the buffers 122a to 122o is used by the main CPU 63 for management. Although the configuration is such that it is transmitted to the IC 66, the configuration is not limited to this, and the correspondence information may be stored in advance in the management IC 66. In this case, since it is not necessary to execute the processing for causing the management IC 66 to recognize the correspondence information, it is possible to reduce the processing load of the main CPU 63.

(17) In the first to fourteenth embodiments, the main CPU 63 to the management IC 66 of the correspondence information indicating the correspondence between the types of information transmitted from the main CPU 63 to the management IC 66 and the buffers 122a to 122o. The transmission to the main CPU 63 is performed at the start of supplying the operating power to the main CPU 63, but the present invention is not limited to this. For example, the main CPU 63 and the management IC 66 can be bidirectionally communicated with each other. The correspondence information may be transmitted from the main CPU 63 to the management IC 66 when a signal requesting the transmission of the correspondence information is received from the IC 66. In this case, the correspondence memory 116 is provided as a non-volatile memory and is used for both reading and writing, and the correspondence information provided from the main CPU 63 to the management IC 66 after the pachinko machine 10 is shipped to the main CPU 63. Even if the supply of operating power is stopped, the correspondence relationship memory 116 stores and holds it. This makes it possible to reduce the frequency with which the correspondence information is transmitted.

(18) In the first to fourteenth embodiments, the main CPU 63 to the management IC 66 of the correspondence information indicating the correspondence between the types of information transmitted from the main CPU 63 to the management IC 66 and the buffers 122a to 122o. Is transmitted using the signal paths 118a to 118g for transmitting the information of the detection results of the respective ball detection sensors 42a to 48a, but the present invention is not limited to this, and the correspondence relationship A dedicated signal path for transmitting information from the main CPU 63 to the management IC 66 may be provided. As a result, the management IC 66 can grasp which type of information is being received from the main CPU 63 by the type of the buffers 122a to 122o that receive the information.

(19) In the first to fourteenth embodiments, the main CPU 63 sends information to the management IC 66, but the management IC 66 does not send information to the main CPU 63. However, the present invention is not limited to this. Instead, information may be transmitted from the management IC 66 to the main CPU 63. For example, various parameters calculated by the management-side CPU 112 based on the history information may be transmitted to the main-side CPU 63. In this case, the main CPU 63 may be configured to directly execute the notification control of the notification means so that the notification corresponding to the contents of the received various parameters is performed. By transmitting the command corresponding to the content of the parameter to the voice emission control device 81, the notification corresponding to the content of the various parameters is executed by using the symbol display device 41, the display light emitting unit 53 and the speaker unit 54. It may be configured to.

(20) In the first to fourteenth embodiments, when the supply of the operating power to the main CPU 63 is started, the main CPU 63 or the management CPU 112 is notified to the main CPU 63 or the management CPU 112 based on the history information stored in the history memory 117. Various parameters may be calculated by using the symbol display device 41, the display light emitting unit 53, the speaker unit 54, and the like to notify the contents of the calculated various parameters. In this case, it is possible to confirm whether or not the entering mode of the game ball in the game area PA on the last business day is normal at the start of the game hall business. Moreover, you may apply the said structure to the said 15th-97th embodiment.

(21) When various parameters calculated based on the history information stored in the history memory 117 in the first to fourteenth embodiments are abnormal results, the pachinko machine 10 is operated until the prohibition cancel operation is performed. It may be configured such that the game cannot be started at. As a configuration that prevents the game from being started, for example, a configuration in which the game ball is prohibited to be launched, a configuration in which each of the ball detection sensors 42a to 49a may be invalidated, and a first operation opening It is also possible to adopt a configuration in which the win/no determination process is not executed even if a win is generated in 33 or the second operating port 34. Further, the prohibition canceling operation may be an operation of turning on the power of the pachinko machine 10 again while the reset button 68c is being pressed, and can be operated when the gaming machine main body 12 is opened to the outer frame 11. The operation means may be operated. As a result, it is possible to prevent the game from being played as it is in a situation where the game balls in the game area PA are in an abnormal mode. Further, it is possible to prevent the game from being played as it is in the situation where the frequency of occurrence of the opening/closing execution mode is abnormal. Moreover, you may apply the said structure to the said 15th-97th embodiment.

(22) Although history information corresponding to the detection results of the ball detection sensors 42a to 48a in the first to fourteenth embodiments is stored in the history memory 117, various parameters are calculated using the history information. The configuration may be such that it is not executed by either the main CPU 63 or the management CPU 112. In this case, the history information may be read by an external device electrically connected to the reading terminal 68d, and the operator of the reading operation may calculate various parameters using the read history information. Of course, the external device may be configured to execute various parameter calculations using the read history information. In this case, the processing load on the main CPU 63 and the management CPU 112 can be reduced. Moreover, you may apply the said structure to the said 15th-97th embodiment.

(23) In the first to fourteenth embodiments, the management IC 66 is provided with a power source different from the main CPU 63, and even if the supply of operating power to the main CPU 63 is stopped, the management IC 66 In the above, the configuration may be such that calculation of various parameters using history information and output of history information or various parameters can be performed. As a result, the history information and various parameters can be read by the external device even when the supply of operating power to the main CPU 63 is stopped.

(24) In the first to fourteenth embodiments, the reading terminal 68d used for reading the program from the main ROM 64 also serves as the terminal used for reading the history information or various parameters by the external device. However, the present invention is not limited to this, and the terminal used for reading the history information or various parameters by the external device is the reading terminal 68d for reading the program from the main ROM 64. It may be configured separately. In this case, the terminal used to read the history information or various parameters may be provided in the MPU 62, or may be provided in a position different from the MPU 62 in the main control board 61.

(25) In the first to fourteenth embodiments, the correspondence relationship memory 116, the history memory 117, and the operation result memory 131 are not limited to the configuration provided as a non-volatile storage unit such as a flash memory. However, for example, one of these memories 116, 117, 131 is provided as a volatile storage means that requires power supply to store and hold information, and backup power is supplied to the memory, so that the main side Information may be stored and held even when the supply of operating power to the CPU 63 is stopped. In this case, a dedicated backup power device may be provided for that memory, or a configuration in which backup power is supplied to the memory from a power supply/launch control device 78 that supplies backup power to the main RAM 65. Good.

(26) In the first to fourteenth embodiments, the management IC 66 includes the management side CPU 112 as a general-purpose CPU, and performs history information storage processing and various parameter calculation processing based on programs and data stored in the management side ROM 113. The configuration to be executed is not limited, and the configuration may be such that a hard circuit designed to have these functions is formed in the management IC 66. More specifically, regarding the configuration, for example, in the case of the first embodiment, when the hardware circuit receives from the main CPU 63 a signal indicating that one of the detection sensors 42a to 48a has detected a game ball. The correspondence relation information corresponding to the buffer that received the signal is stored in the history memory 117 from the correspondence relation memory 116, and the RTC 115 information at that time is stored in the history memory 117. To do. Further, for example, in the case of the sixth embodiment, when the hardware circuit receives a signal indicating that the game ball is detected by any of the detection sensors 42a to 48a from the main CPU 63, that signal is received. The value of the counter corresponding to the buffer is incremented by 1. In addition, the hardware circuit calculates various parameters by using the history information at the time when the calculation trigger in the first embodiment or the like occurs. Further, when an external output trigger to the reading terminal 68d is generated, the hardware circuit externally outputs various parameters that are calculation results and the history information.

(27) In the first to fourteenth embodiments described above, the main CPU 63 and the management IC 66 may be provided as separate chips or may be provided as separate boards, and different control devices may be provided. It may be configured to be provided as.

(28) Regarding the number of game balls entering the out port 24a, the number of game balls is measured, while the number of game balls such as the general winning port 31, the special electric winning device 32, the first operating port 33, and the second operating port 34 History information including RTC information may be stored with respect to the payout of prize balls and the entry into the privilege-triggered entry ball portion, which serves as an opportunity for the determination process. As a result, it is possible to calculate the frequency of game balls entering each privilege opportunity ball unit with respect to the total number of discharged game balls, while allowing the history of game balls entering the privilege opportunity ball unit to be extracted. Become.

(29) The predetermined event that triggers the storage of the history information may include those other than those in each of the above embodiments. For example, at least one of the timing when the lower plate 56a becomes full, the timing when the full state is started, and the timing when the full state is released may be stored as history information. At least one of the time when the non-ball state is started, the timing when the no-ball state is started, and the timing when the no-ball state is released may be stored as history information, and the dispensing device 76 is in an abnormal state. That is, at least one of the timing at which the abnormal state of the dispensing device 76 is started and the timing at which the abnormal state of the dispensing device 76 is released may be stored as history information. In this case, it is possible to grasp the occurrence frequency of these events.

(30) In the first embodiment, the 16th buffer 122p of the input port 121 in the management-side I/F 111 is set in advance in the design stage of the management IC 66 so as to correspond to the output instruction signal. However, the configuration is not limited to this, and the configuration in which the 16th buffer 122p corresponds to the output instruction signal is also recognized by the management IC 66 when the type identification command is transmitted from the main CPU 63. May be Further, in the first embodiment, it is set in advance that the fifteenth buffer 122o of the input port 121 in the management-side I/F 111 corresponds to the set value update signal in the design stage of the management IC 66. However, the present invention is not limited to this, and the fact that the fifteenth buffer 122o corresponds to the set value update signal is also recognized by the management IC 66 when the type identification command is transmitted from the main CPU 63. It may be configured. In this case, it is not necessary to previously set the correspondence between the buffers 122a to 122p and the types of signals input to the buffers 122a to 122p in the management IC 66 in advance.

(31) In the first to fourteenth embodiments, the management IC 66 may be configured to send a normal operation signal to the main CPU 63 when it is operating normally. In this case, it becomes possible for the main CPU 63 to monitor whether the management IC 66 is operating normally.

(32) The display device that displays the setting value being updated in the setting value updating process is not limited to the first to fourth notification display devices 201 to 204, and may be the symbol display device 41, It may be a dedicated display device. Further, the display device that displays the set value in the setting confirmation process is not limited to the first to fourth notification display devices 201 to 204, and may be the symbol display device 41, or a dedicated display device. May be

(33) The operation unit operated to update the set value in the set value update process is not limited to the update button 68b and may be the reset button 68c. Further, the position corresponding to each of "Setting 1" to "Setting 6" is set as the rotation operation position when the setting key is inserted into the setting key insertion portion 68a and the rotation operation is performed. A set value corresponding to the rotational operation position of the portion 68a may be set. Further, the setting key insertion portion 68a is configured to be able to be rotated further than the ON position, and each time the rotating operation beyond the ON position is performed, the set value being updated becomes the set value in the next order. The configuration may be updated.

(34) In the first to tenth and fifteenth to twenty-first embodiments, the first to third notification display devices 69a to 69c are arranged side by side, but they are arranged vertically. The configuration may be such that they are arranged side by side, or they may be arranged side by side obliquely, or may be arranged side by side so as to be in two stages above and below. Further, although the first to fourth notification display devices 201 to 204 are arranged side by side in the above-described first to fourteenth and twenty-second to seventy-sixth embodiments, they are arranged side by side in the vertical direction. The configuration may be such that they are arranged side by side obliquely, or that they are arranged side by side so as to be in two stages above and below. Further, in the fifteenth to twenty-first embodiments, the first to fourth notification display devices 201 to 204 may be used as display devices for displaying the game history management results.

(35) In the first to fourteenth embodiments described above, history information (hereinafter referred to as variation target history information) used to calculate a parameter whose normal value varies according to the setting state of the pachinko machine 10. ) And history information (hereinafter referred to as non-variation target history information) used for calculating a parameter whose normal value does not fluctuate according to the setting state of the pachinko machine 10, in different areas in the history memory 117. It may be configured to be stored in. In this case, when the setting state of the pachinko machine 10 is newly set or when the setting state of the pachinko machine 10 is changed, the area in which the history information of the change target is stored in the history memory 117 is “0”. On the other hand, the area of the history memory 117 in which the history information of the non-variation target is stored may be cleared to "0" while being cleared. Thereby, the calculation of the parameter whose normal value fluctuates according to the setting state of the pachinko machine 10 can be accurately performed even after the setting value is changed, and the normal value does not fluctuate according to the setting state of the pachinko machine 10. The accuracy of parameter calculation can be improved. Moreover, you may apply the said structure to the said 15th-97th embodiment.

(36) In the fifteenth to twenty-first embodiments, the stack area 222 for specific control and the stack area 224 for non-specific control may not be designated in advance in the main RAM 65. Even in this case, the areas corresponding to the stack areas 222 and 224 are specified in the main RAM 65 at the design stage of the pachinko machine 10, but the areas are specified beyond the storage capacity of the areas. When the information storage process is executed, the originally unscheduled information is written in the originally unscheduled area, so that the main RAM 65 may be cleared to “0”.

(37) In the fifteenth to twenty-first embodiments, when the main RAM 65 clearing process (step S105, step S117) is executed, the work area 221 for specific control and the stack area 222 for specific control are Although it is cleared to "0", the work area 223 for non-specific control and the stack area 224 for non-specific control are not cleared to "0". Instead, the clear processing of the main RAM 65 (step S105, In step S117), not only the work area 221 for specific control and the stack area 222 for specific control but also the work area 223 for non-specific control and the stack area 224 for non-specific control may be cleared to "0". .. Further, in the clear processing of the main RAM 65 (steps S105 and S117), not only the work area 221 for specific control and the stack area 222 for specific control, but also the normal counter area 231, the opening/closing execution mode counter area 232, and the high frequency Although the support mode counter area 233 is cleared to “0”, the calculation result storage area 234 may not be cleared to “0”. In this case, the information stored in the calculation result storage area 234 can be protected.

(38) In the fifteenth to twenty-fifth embodiments described above, an operation for clearing the work area 221 for specific control and the stack area 222 for specific control to "0", and a work area 223 for non-specific control and a non-specific control area The operation for clearing the stack area 224 for specific control to “0” may be different from each other. For example, when supply of operating power to the pachinko machine 10 is started while operating the reset button 68c, the work area 221 for specific control and the stack area 222 for specific control are cleared to "0", and the update button 68b is clicked. When the supply of operating power to the pachinko machine 10 is started during operation, the work area 223 for non-specific control and the stack area 224 for non-specific control may be cleared to “0”. This makes it possible to selectively erase each piece of information. Further, in the configuration, when supply of operating power to the pachinko machine 10 is started while operating both the update button 68b and the reset button 68c, the work area 221 for specific control and the stack area 222 for specific control are provided. Alternatively, the work area 223 for non-specific control and the stack area 224 for non-specific control may all be cleared to "0". This makes it possible to improve workability in the case of collectively erasing information in the areas 221 to 224 in the configuration that allows selective erasing as described above.

(39) Similar to the nineteenth embodiment in the fifteenth to eighteenth and twentieth embodiments, when the processing corresponding to the non-specific control is started, the information of the stack pointer of the main CPU 63 is the work for the non-specific control. The saved information may be saved in the area 223 and returned to the stack pointer of the main CPU 63 when returning to the process corresponding to the specific control. As a result, even if the information of the stack pointer of the main CPU 63 can be changed when the process corresponding to the non-specific control is started, when the process corresponding to the non-specific control is completed, the main side can be changed. The state of the stack pointer of the CPU 63 can be returned to the state before the process corresponding to the non-specific control is started.

(40) Processing for collecting game history information as processing corresponding to non-specific control in the fifteenth to twenty-fifth embodiments, processing for calculating various parameters using the collected history information, and Although the processing for notifying the calculation result is executed, only a part of these processing is executed as the processing corresponding to the non-specific control, and the other is executed as the processing corresponding to the specific control. May be Further, in addition to or instead of the process for collecting information on the game history, the process for calculating various parameters using the collected history information, and the process for notifying the calculation result, other than these processes The process may be executed as a process corresponding to the non-specific control. For example, at least one of the illegality monitoring and the notification of the monitoring result may be executed as a process corresponding to the non-specific control.

(41) In the fifteenth to twenty-fifth embodiments described above, when returning to the process corresponding to the specific control from the situation where the process corresponding to the non-specific control is being executed in the main CPU63, the flag register of the main CPU63, Although neither the stack pointer nor the various registers are saved in the main side RAM 65, instead of this, the main side CPU 63 executes the process corresponding to the non-specific control to the process corresponding to the specific control. When returning, information of at least a part of the flag register, stack pointer, and various registers of the main CPU 63 is saved in the main RAM 65, and the saved information restarts the process corresponding to the non-specific control. In this case, the main CPU 63 may be restored to the corresponding storage area. As a result, the information of the main CPU 63 used in the process corresponding to the non-specific control can be carried over and used.

(42) In the fifteenth to twenty-fifth embodiments described above, various parameters are calculated in response to the total number of game balls discharged from the game area reaching 6000. The total number of game balls may be larger or smaller than 6000. For example, various parameters may be calculated when the total number of game balls discharged from the game area reaches 60000. In this case, although the storage capacity necessary for storing the information on the game history is increased, the information on the game history is stored in the management RAM 241 externally attached to the MPU 62 as in the twenty-first embodiment. With the configuration of storing, it becomes possible to flexibly cope with the increase of the storage capacity.

(43) In the fifteenth to twenty-fifth embodiments, the sixty-first to sixty-eighth parameters are calculated as the game history management result. However, in addition to or instead of this, the thirty-first parameter in the first embodiment is used. At least a part of the parameters, the 41st parameter, and the 42nd parameter may be calculated.

(44) In the fifteenth to twenty-fifth embodiments, when the process of newly setting the setting state of the pachinko machine 10 is executed or when the setting state of the pachinko machine 10 is changed, the work area 221 for specific control is set. Also, not only the stack area 222 for specific control but also the work area 223 for non-specific control and the stack area 224 for non-specific control may be cleared to “0”. In this case, when the process of newly setting the setting state of the pachinko machine 10 is executed or when the setting state of the pachinko machine 10 is changed, the normal counter area 231, the opening/closing execution mode counter area 232, the high frequency The support mode counter area 233 and the calculation result storage area 234 are cleared to “0”.

Further, when a process of newly setting the setting state of the pachinko machine 10 is executed or when the setting state of the pachinko machine 10 is changed, not only the work area 221 for specific control and the stack area 222 for specific control The normal counter area 231, the open/close execution mode counter area 232, and the high frequency support mode counter area 233 may be cleared to “0”, but the calculation result storage area 234 may not be cleared to “0”. In this case, the information stored in the calculation result storage area 234 can be protected.

In addition, when the process of newly setting the setting state of the pachinko machine 10 is executed or when the setting state of the pachinko machine 10 is changed, the work area 221 for specific control and the stack area 222 for specific control are set to “0. The work area 223 for non-specific control and the stack area 224 for non-specific control, which are cleared, may not be cleared to “0”. In this case, the information stored in the non-specific control work area 223 and the non-specific control stack area 224 can be protected.

Further, when the configuration of (43) is provided, when the process of newly setting the setting state of the pachinko machine 10 is executed or the setting state of the pachinko machine 10 is changed, the first Although the history information for calculating the 31st parameter, the 41st parameter, and the 42nd parameter in the above embodiment is deleted, the normal counter area 231, the open/close execution mode counter area 232, and the high frequency support mode counter area 233 are deleted. The calculation result storage area 234 may not be cleared to "0".

(45) In the first to 97th embodiments described above, instead of the configuration in which the total number of discharged game balls discharged from the game area PA is used to calculate various parameters, the game balls are supplied to the game area PA. The configuration may be such that the total supply number of game balls is used. In this case, for example, a detection sensor is provided so as to detect a game ball that has been launched from the game ball launching mechanism 27 and has reached the game area PA, and the game ball supplied to the game area PA based on the detection result of the detection sensor. The number may be measured. In this configuration, since it is not necessary to count the number of game balls discharged from the outlet 24a, the outlet detection sensor 48a may not be provided.

(46) In the fifteenth to ninety-seventh embodiments, at least a part of the information of various registers and stack pointer of the main CPU 63 is stored in the stack area 222 for specific control or the stack area 224 for non-specific control. It may be configured to be saved by a load instruction. In this case, it is necessary to update the information of the stack pointer of the main CPU 63 when saving the information in the stack areas 222 and 224. Further, the information saved in the stack areas 222 and 224 may be restored to the corresponding storage area of the main CPU 63 by a load instruction. Also in this case, it is necessary to update the information of the stack pointer of the main CPU 63 when the information is returned from the stack areas 222 and 224.

(47) When the set value update process is executed in each of the above-described embodiments, the notification corresponding to the process may be performed by any of the symbol display device 41, the display light emitting unit 53, and the speaker unit 54. This allows the manager of the game hall to clearly understand that the setting value update process is being executed.

(48) In each of the above embodiments, the history that the setting value is newly set may be stored in the main RAM 65. Further, the history that the set value is newly set may be stored in the RAM provided in the voice emission control device 81. In this case, every time the set value update process is completed, a command including information about the set value set in the set value update process is transmitted from the main CPU 63 to the sound emission control device 81, and the sound emission control device 81 Each time 81 receives the command, the information indicating that the set value is newly set and the information indicating the set value at that time are cumulatively stored in the RAM of the sound emission control device 81. When a predetermined operation is performed in this configuration, the setting history of the setting values cumulatively stored in the RAM of the voice emission control device 81 may be displayed on the symbol display device 41.

(49) In each of the above-described embodiments, when the set value is newly set in the set value updating process, the information indicating the number of game balls to be paid out, which is stored in the payout control device 77, is not erased. However, instead of this, the information indicating the number of game balls to be paid out may be deleted. In addition, if the set value is not changed even though the set value update process has been executed, the information indicating the number of gaming balls to be paid out is not erased, and if the set value is changed, the payout is planned to be paid out. The information indicating the number of game balls may be deleted.

(50) When the setting value updating process is executed in each of the above-mentioned embodiments, but the setting value is not changed, the areas 221 to 224 of the main RAM 65 are not cleared to "0" and the setting value is When changed, at least a part of each of the areas 221 to 224 of the main RAM 65 may be cleared to "0". For example, when the set value is changed, the area other than the set value counter in the work area 221 for specific control may be cleared to "0".

(51) Even in the situation where the processing for confirming the setting value in the setting confirmation processing (FIG. 87) is being executed in the main CPU 63 in the above twenty-second to ninety-seventh embodiments, it is in the profit of the game. The movable object involved may be continuously operated. For example, a V-zone and a non-V zone are provided in the ball-entering means that can enter the ball in the opening/closing execution mode, and the game ball entered in the ball-entering means is distributed to either the V-zone or the non-V-zone. In the configuration including the distribution member, the operation of the distribution member may be continued even in the situation where the process for confirming the set value is being executed in the setting confirmation process. In this case, even if an attempt is made to stop the operation of the distribution member by improperly generating a situation in which the processing for confirming the setting value is executed in the setting confirmation processing, it is possible to disable it. It should be noted that, in addition to the above-mentioned distribution member, a game that has entered the ball entering means is a movable object that continues to operate even if the processing for confirming the setting value is executed in the setting confirmation processing. The game ball is placed in either the advantageous port that will generate a round game after the ball enters or the discharge port that discharges the game ball that entered the ball entry means without entering the advantageous ball. A distribution member for distribution can be considered.

(52) In the twenty-second to ninety-seventh embodiments, at least one of the non-specific control work area 223 and the non-specific control stack area 224 may be configured not to be monitored for information abnormality. In this case, even if it is specified that the information abnormality has occurred in the work area 221 for specific control and the stack area 222 for specific control, the work area 223 for non-specific control and the stack area for non-specific control are provided. By setting the configuration in which 224 is not cleared to "0", the situation where the work area 223 for non-specific control and the stack area 224 for non-specific control is not cleared to "0" based on the occurrence of information abnormality is prevented. It becomes possible to do.

(53) In the twenty-ninth to ninety-seventh embodiments, there is an information abnormality in the specific control work area 221, the specific control stack area 222, the non-specific control work area 223, and the non-specific control stack area 224. It is also possible to adopt a configuration in which all the monitoring of whether or not it has occurred is executed in the processing corresponding to the non-specific control. Further, the configuration for clearing the areas 221 to 224 to “0” when an information abnormality occurs may be executed by the process corresponding to the non-specific control.

(54) In each of the above-described embodiments, the main RAM 65 needs to be supplied with power to store and hold information, and backup power is supplied to the main RAM 65 even when the pachinko machine 10 is powered off. However, the main RAM 65 may be a non-volatile memory that does not require power supply to store and retain information.

(55) In each of the above-described embodiments, in the various clearing processes of the main RAM 65, the target area of the main RAM 65 is initialized by performing a process of clearing “0” and an initializing process. Alternatively, the target area may be initialized by executing a process of initializing without executing a process of clearing “0”.

(56) In each of the above-mentioned embodiments, when the supply of the operating power to the main CPU 63 is started and the setting key insertion portion 68a is turned on, the setting value update processing is executed without any other operation. It may be configured to be. Further, instead of the setting key inserting section 68a which is turned on and off by the setting key, a setting switch which is turned on and off directly by hand may be provided. Further, if the setting key insertion portion 68a is not provided and the reset button 68c is pressed when the supply of operating power to the main CPU 63 is started, the setting value can be set without any other operation. The update process may be executed. In this case, a cover member may be provided so that the reset button 68c can be switched between a closed state and an uncovered open state. The locking device locks the cover member at the closed position. May be provided.

(57) A configuration in which the setting value being selected is confirmed and the setting value updating processing is ended when the state where the setting key insertion portion 68a is operated to the OFF position is held for a predetermined period in the setting value updating processing. May be Further, when the end reference period (for example, 5 minutes) has elapsed since the setting value updating process was started, the selected setting value may be automatically determined and the setting value updating process may be ended. Further, in the setting value updating process, when the update button 68b or the reset button 68c is pressed for a longer than the end reference period (for example, 10 seconds), the selected setting value is confirmed and the setting value updating process is ended. It may be configured.

(58) The setting key insertion portion 68a is configured to be able to be rotated further than the ON position, and each time the rotating operation beyond the ON position is performed, the set value being updated is the set value in the next order. In the configuration that is updated to, the setting confirmation processing that enables confirmation of the set value is started when the supply of operating power to the main CPU 63 is started in the situation where the setting key insertion portion 68a is operated to the ON position. The setting confirmation process may be terminated when the setting key insertion unit 68a is operated to the OFF position. Also, when the update button 68b or the reset button 68c is pressed, when the supply of operating power to the main CPU 63 is started, the setting confirmation process that enables confirmation of the set value is started, and The configuration confirmation process may be terminated when the pressing operation is released. Further, in a configuration in which a setting switch that is directly turned on and off by a hand is provided instead of the setting key insertion portion 68a that is turned on and off by the setting key, it is mainly used when the setting switch is turned on. When the supply of operating power to the side CPU 63 is started, a setting confirmation process that enables confirmation of a set value is started, and when the setting switch is turned off or turned on after the off operation. The configuration confirmation process may be terminated. Further, in a configuration in which a setting switch that is directly turned on and off by a hand is provided instead of the setting key insertion portion 68a that is turned on and off by the setting key, it is mainly used when the setting switch is turned on. When the supply of operating power to the side CPU 63 is started, the setting confirmation process that enables confirmation of the set value is started, and when the reset button 68c is pressed, the setting confirmation process is ended. Good.

(59) In the case where the setting confirmation process or the setting value update process is executed in each of the above-described embodiments, the image corresponding to the procedure may be configured to be displayed on the symbol display device 41, so as to assist it. The voice corresponding to the procedure may be output from the speaker unit 54. For example, in the set value updating process in the thirty-third embodiment, the set value is changed by one step by pressing the reset button 68c, and the set value updating process is ended by turning off the setting key inserting section 68a. The configuration may be such that it is notified. This facilitates the work of updating the set value. Since the display control of the symbol display device 41 and the sound output control of the speaker unit 54 are performed by the voice emission control device 81, when the setting confirmation process or the set value update process is started, the command corresponding to it is issued. When the setting confirmation process or the setting value updating process is transmitted from the main CPU 63, the corresponding command needs to be transmitted from the main CPU 63.

(60) In order to end the check display of the first to fourth notification display devices 201 to 204 in each of the above embodiments, not to end the initial check period The check display may be continued until an operation is performed. As the operation for ending the operation, for example, the reset button 68c may be operated regardless of whether any one of the setting confirmation processing and the set value updating processing is executed, and an operation other than the reset button 68c. The unit may be operated. In this case, the check display is continued on the first to fourth notification display devices 201 to 204 until it is time to confirm the base value or the set value on the first to fourth notification display devices 201 to 204. Therefore, it becomes possible to confirm the base value or the set value after confirming whether or not the first to fourth notification display devices 201 to 204 are normal. Moreover, since the check display is ended based on the operation of the operation unit, the check display can be ended at a desired timing.

(61) The first to fourth notification display devices when a predetermined operation unit such as the update button 68b or the reset button 68c is operated regardless of whether or not the supply of the operating power is started in each of the above embodiments. The check display of 201 to 204 may be started. In this case, the check display can be started at a desired timing when confirming the base value or the set value. Further, in the configuration, the check display may be terminated when a predetermined period (for example, 5 seconds) has passed, and the predetermined operation unit operated to start the check display or another operation unit different from the predetermined operation unit. The check display may be terminated when the operation unit is operated.

(62) In each of the above-described embodiments, when the supply of the operating power to the main CPU 63 is started in the state where a specific operation unit other than the reset button 68c such as the update button 68b is operated, the first to fourth notifications are given. The check display may not be started when the check display of the display devices 201 to 204 is started and the supply of the operating power to the main CPU 63 is started without operating the specific operation unit. .. In this case, in the configuration in which the check display is performed when the supply of the operating power is started, it is possible to select whether or not the check display is started by the operation of the game hall manager.

(63) In each of the above embodiments, the base value is not displayed on the first to fourth notification display devices 201 to 204 regardless of whether the gaming machine body 12 is in the open state, but rather the gaming machine body. When the open state of 12 is specified based on the detection result of the main body open sensor 96, the base value may be displayed on the first to fourth notification display devices 201 to 204. In this case, when the gaming machine main body 12 is in the open state, first the check display of the first to fourth notification display devices 201 to 204 is started, and then the first to fourth notification display devices 201 to 201. The base value may be displayed at 204. Thereby, before confirming the base value, it is possible to confirm whether or not the first to fourth notification display devices 201 to 204 are normal. Further, in the configuration, the check display may be terminated when a predetermined period (for example, 5 seconds) has passed, and the predetermined operation unit operated to start the check display or another operation unit different from the predetermined operation unit. The check display may be terminated when the operation unit is operated.

(64) In the above embodiments, when the main process is started while the condition for executing the setting check process is satisfied, the check display of the first to fourth notification display devices 201 to 204 is started. Alternatively, the check display may be started when the main process is started in a state where the condition for executing the setting check process is not satisfied. In this case, if it is confirmed that the set value is confirmed, it is possible to prevent the check display from being displayed.

(65) In the above embodiments, when the main process is started in a state where the condition for executing the set value update process is satisfied, the check display of the first to fourth notification display devices 201 to 204 is started. Alternatively, the check display may be started when the main process is started in a state where the condition for executing the set value update process is not satisfied. In this case, it is possible to prevent the check display from being displayed when it is determined that the setting value will be updated.

(66) First to fourth notifications when the main process is started in a state where either the condition for executing the setting confirmation process or the condition for executing the setting value update process is satisfied in each of the above embodiments When the main display is started in a state in which both the condition for executing the setting confirmation process and the condition for executing the setting value update process are not satisfied without the check display of the display devices 201 to 204 being started. The check display may be started. In this case, when it is confirmed that the set value is confirmed or the set value is updated, it is possible to prevent the check display from being displayed.

(67) In the check display in each of the above embodiments, the display segments 321 to 324 in each of the first to fourth notification display devices 201 to 204 are not maintained in the light emitting state, but rather in the first to fourth Each of the display segments 321 to 324 in each of the notification display devices 201 to 204 may be in a blinking state. Further, in the check display, each of the display segments 321 to 324 in the first to fourth notification display devices 201 to 204 sequentially emits light one by one or a plurality of some of them, and the range of the initial check period Each of the display segments 321 to 324 may be in a light emitting state at least once.

(68) In each of the above-described embodiments, the process of causing the first to fourth notification display devices 201 to 204 to perform the check display is not executed as the process corresponding to the specific control, but corresponds to the non-specific control. It may be configured to be executed as a process.

(69) In each of the above embodiments, the display control of the first to fourth notification display devices 201 to 204 may be performed not by the main CPU 63 but by dedicated control means. The configuration may be performed by 81 or the display control device 82. In this case, when displaying the base value on the first to fourth notification display devices 201 to 204, the base value to be notified is transmitted from the main CPU 63 to the control means that is the control subject, and When the set values are displayed on the fourth notification display devices 201 to 204, the set values to be notified are transmitted from the main CPU 63 to the control means serving as the control subject. When the main CPU 63 executes the process at the time of starting the supply of the operating power, the first to fourth notification display devices 201 to 204 are displayed in the situation where the process at the start of supplying the operating power is being executed. Thus, the information corresponding to the start of the check display is transmitted from the main CPU 63 to the control means that is the control subject so that the check display is started.

(70) In the above embodiments, when the power failure flag is not set to "1" or the checksums do not match, the game stop flag is set to "1" and the game progress is stopped. In each of the first to fourth notification display devices 201 to 204, each display segment 321 to 324 may be in a light emitting state similarly to the check display, or each display segment 321 to 324 may be in a blinking state. Good.

(71) The set value is set not only when the supply of the operating power to the main CPU 63 is started in each of the above-described embodiments but also when the setting change trigger is generated after the process at the start of the supply of the operating power is completed. The configuration may be such that the update process is executed. As a result, it becomes possible to prevent the pachinko machine 10 from turning OFF and ON when starting the set value updating process.

(72) In each of the above-described embodiments, the “setting change operation” and the “setting confirmation operation” may have a reverse relationship. That is, when the reset button 68c is pressed and the setting key insertion portion 68a is turned ON, it is specified that the "setting confirmation operation" is performed, and the reset button 68c is not pressed and the setting is performed. A configuration may be specified in which the "setting change operation" is performed when the key insertion portion 68a is turned on. Further, the operation may not be overlapped between the “setting change operation” and the “setting confirmation operation”.

(73) In each of the above-described embodiments, the set value update process is started based on the fact that the supply of the operating power to the main CPU 63 is started while the reset button 68c is being pressed, and the set value update process is also performed. In the configuration described above, the setting value of the selection target is not changed every time the reset button 68c is pressed, but the operation unit operated to start the setting value update process and the selection target in the setting value update process are changed. The configuration may be such that the operation unit operated to change the setting value of does not match.

(74) In the 49th to 81st and 88th embodiments, the process of setting the information of the setting update area 342 in the setting reference area 341 in the setting value update process, that is, the process of setting the setting value to be used Although the second RAM clearing process is performed after performing the above, the present invention is not limited to this, and the second RAM clearing process may be performed before performing the process of setting the setting value to be used. .. In this case, the second RAM clearing process may be executed instead of the initial setting at the start in the setting value updating process.

In addition, in the setting value updating process, neither the initial setting at the start nor the second RAM clearing process is executed, so that the clearing target area 371 is set even if the setting value to be used is set in the setting value updating process. The configuration may be such that the initialization of is not executed. When the configuration is applied to the 55th to 63rd embodiments, when the first RAM clear process is performed by performing the “RAM clear operation”, the clear target area 371 is initialized. When the set value update process is executed, the initialization of the clear target area 371 is not executed. Further, when the above configuration is applied to the 56th embodiment, the initial display may be performed on the special figure display unit 37a and the general figure display unit 38a even if the setting value updating process is executed. The initial display may not be performed. Further, when the above configuration is applied to the 57th to 58th embodiments, even if the set value updating process is executed, the special figure display unit 37a and the general figure display unit 38a are configured to display the deviation. It is also possible to adopt a configuration in which the disconnection display is not performed. Further, when the above configuration is applied to the 59th to 60th embodiments, even if the set value updating process is executed, the special figure display unit 37a and the general figure display unit 38a perform the misalignment display or the hit display. It is also possible to adopt a configuration in which the deviation display or the hit display is not performed. Further, when the above configuration is applied to the sixty-first embodiment, even if the set value updating process is executed, the respective light emitting units of the special figure display unit 37a and the general light display unit 38a are turned on. The lottery process may be executed, or the lighting lottery process may not be executed. When the above configuration is applied to the 62nd to 76th embodiments, the initial display data lottery process (step SD405) in the display start process (FIGS. 206 and 208) even if the setting value update process is executed. , Step SD410, step SD502) may be performed, or the initial display data lottery process (step SD405, step SD410, step SD502) may not be performed.

(75) In the 49th to 81st and the 88th embodiments, the display data for causing the special figure display portion 37a to display is stored in the main RAM 65 that requires power supply when storing and holding information. Instead of the configuration, the display data may be stored in a memory that does not need to be supplied with power when storing and holding information and is used for both reading and writing. In this case, the display data stored in the memory may not be erased during the first RAM clearing process and the second RAM clearing process, and the clear target area 371 is initialized during the first RAM clearing process and the second RAM clearing process. The display data stored in the memory may also be erased. Further, the configuration may be applied to the display data for causing the general figure display unit 38a to display.

(76) In the above 55th to 76th embodiments, the special-drawing-side hold information acquired by the winning of the first working opening 33 and the winning information of the second working opening 34 are acquired. It is also possible to apply a configuration in which the stored information on the special map side is stored separately, and the retained information on the second actuating port 34 side is preferentially consumed. A configuration may be applied in which the pending information on the 33 side is preferentially consumed, and a configuration in which the reservation information is consumed in the acquisition order regardless of whether it is the first operation port 33 or the second operation port 34 is applied. Good. Further, in the above configuration, the plurality of operating ports may not be arranged side by side in the vertical direction, but the first operating port 33 and the second operating port 34 may be arranged side by side in the left and right directions. The mouths may be arranged obliquely side by side. Furthermore, depending on the operation mode of the firing operation device 28, both the working ports 33, 34 are arranged apart from each other so that only the winning in the first working port 33 or only the winning in the second working port 34 can be aimed. It may be configured. In addition, when the hold information acquired due to the occurrence of a prize in the first operating port 33 is the target of the winning/disapproval determination, and the hold information acquired due to the occurrence of a prize in the second operating port 34 is The profit obtained by the player may be different from that of the case where the judgment is made.

Further, in the above-described configuration, as the special figure display unit 37a, the first special figure display unit that displays the result of the determination of whether or not the hold information acquired based on the winning of the first working port 33 is displayed, and the second working port 34. You may separately provide the 2nd special figure display part which displays the result of the success/failure determination of the hold information acquired based on the winning of. In this case, the hold information acquired based on the winning of the first working opening 33 is applied to the first special map display unit prior to the target of the success/failure determination or the target of the success/failure determination. The variable display is started and the stop result corresponding to the win/fail judgment is displayed, and the variable display for one game is ended. Further, based on the fact that the hold information obtained based on the winning of the winning on the second operating port 34 is the target of the success/failure determination or is the target of the success/failure determination, the pattern is displayed on the second special figure display portion. When the variable display is started, the stop result corresponding to the win/fail judgment is displayed, and the variable display for one game is ended.

In the configuration in which the first special figure display unit and the second special figure display unit are provided as described above, the special figure display unit 37a when the supply of the operating power in the 55th to 63rd embodiments is started The configuration of the display content of may be applied to each of the first special figure display section and the second special figure display section, and may be applied to only one of the first special figure display section and the second special figure display section. May be.

In the structure in which the first special figure display unit and the second special figure display unit are individually provided as described above, one of the first special figure display unit and the second special figure display unit is displayed as a variable display of the pattern. When the target game time is being executed, the other game time may be configured such that the other game time is set as the pattern variable display target. Further, it may be configured such that the game times in which the first special figure display unit is subjected to the variable display of the pattern and the game times in which the second special figure display section is subjected to the variable display of the pattern can be executed in an overlapping manner. In such a configuration in which the game times can be executed in an overlapping manner, as a result of the game times in the second special map display unit, the expected number of winning game balls to the special electric prize winning device 32 in the opening/closing execution mode is larger than the case of the jackpot result. It is also possible to set a small hit result that is smaller than that, and a winning probability of the small hit result is set to be higher than the big hit result. In this configuration, when the supply of operating power is stopped, it is highly possible that the special figure display unit 37a displays a hit corresponding to either the big hit result or the small hit result. Therefore, when the first RAM clearing process or the second RAM clearing process is executed when the supply of the operating power is started, the first to third deviation display data for special figures and It is preferable that any one of the first to third hit display data for special drawings is selected.

(77) In the 55th to 76th embodiments, the configuration of the characteristic display contents when the supply of the operating power is started is applied to both the special figure display section 37a and the general figure display section 38a. The configuration is not limited, and the configuration may be applied to only one of the special figure display unit 37a and the general figure display unit 38a. For example, the configuration of the characteristic display contents when the supply of operating power is started may be applied only to the special figure display portion 37a, or may be applied only to the general figure display portion 38a. Good.

(78) In the fifty-fifth to seventy-sixth embodiments, even if the supply of the operating power to the main CPU 63 is started, the special figure display portion 37a and the universal figure are displayed until the display start flag is set to "1". Although the display of the display unit 38a is not started, the present invention is not limited to this, and the display start flag is not provided, and when the supply of the operating power to the main CPU 63 is started, it is special. The display on the figure display unit 37a and the general figure display unit 38a may be started. In this case, if the first RAM clearing process or the second RAM clearing process is executed when the supply of the operating power is started, the supply of the operating power is stopped in the special figure display unit 37a and the general figure display unit 38a. After the immediately preceding display is started, the display contents of the special figure display portion 37a and the general figure display portion 38a are switched to the display corresponding to the execution of the first RAM clear processing or the second RAM clear processing.

(79) In the 77th to 81st embodiments, the sound/light side CPU 353 receives the sound/light side RAM initialization processing based on the receipt of any of the return commands from the main CPU 63, and the received return command. Although the notification setting process corresponding to is executed, the present invention is not limited to this. Specifically, only one of the sound-light side RAM initialization process and the post-update notification setting process may be executed based on the sound-light side CPU 353 having received the update return command. It may be configured such that only one of the sound-light side RAM initialization process and the post-confirmation notification setting process is executed based on the light-side CPU 353 having received the confirmation return command, and when the sound-light side CPU 353 is clear. It may be configured such that only one of the sound-light side RAM initialization processing and the clear return notification setting processing is executed based on the reception of the sound-light side return command, and that the sound-light side CPU 353 receives the normal return command. Based on this, only one of the sound/light side RAM initialization processing and the normal recovery notification setting processing may be executed.

(80) In the above 88th embodiment, the sound/light side CPU 353 responds to the sound/light side RAM initialization processing based on the receipt of any of the return commands from the main CPU 63, and the received return command. Although the notification setting process is executed, the present invention is not limited to this. Specifically, only one of the sound-light side RAM initial setting process and the post-update notification setting process may be executed based on the sound-light side CPU 353 having received the update return command. Only one of the sound-light side RAM initial setting process and the post-confirmation notification setting process may be executed based on the light-side CPU 353 having received the confirmation return command, and when the sound-light-side CPU 353 is clear. It may be configured such that only one of the sound-light side RAM initial setting process and the clear return notification setting process is executed based on the reception of the sound-light-side restoration command. Based on this, only one of the sound/light side RAM initial setting process and the normal return notification setting process may be executed.

(81) In the above-mentioned 82nd embodiment, when the supply of the operating power to the main CPU 63 is started, it is determined whether or not the past base value is within the normal base range (0.30 to 0.40). If it is determined that the past base value is out of the normal base range in the abnormality determination, the representative value data corresponding to the base value may be externally output to an external device such as the data display DI. .. Further, in the 83rd embodiment, when the supply of the operating power to the main CPU 63 is started, an abnormality determination is performed to determine whether or not the past base value is within the normal base range (0.30 to 0.40). When it is determined in the abnormality determination that the past base value is out of the normal base range, the processing representative value data corresponding to the base value may be externally output to an external device such as the data display DI. .. By externally outputting the representative value data or the processed representative value data corresponding to the past base value, it is possible to reduce the possibility that the abnormality of the base value is overlooked.

(82) In the above 84th to 87th embodiments, the case where the past base value is out of the normal base range (0.35 to 0.40) at the time of starting the supply of the operating power to the main CPU 63 corresponds. Although the base value abnormality signal is externally output to the abnormality alarm EI, the present invention is not limited to this, and the supply of operating power to the main CPU 63 is started at a predetermined time interval (for example, 4 hours interval). An abnormality determination is performed to determine whether or not the past base value in the first history area 312 to the third history area 314 is within the normal base range, and any one of the past base values in the abnormal determination is the normal base range. If it is out of the range, the corresponding base value abnormality signal may be externally output to the abnormality alarm device EI. When any of the past base values is abnormal in the abnormality determination performed at the predetermined time interval, the base value abnormality signal is externally output in the 84th embodiment, and the upper base value is output in the 85th embodiment. The abnormality signal or the lower base value abnormality signal is externally output, and in the 86th embodiment, the upper base value abnormality signal, the lower first base value abnormality signal, or the lower second base value abnormality signal is externally output, In the 87th embodiment, the common base value abnormality signal and the upper base value abnormality signal or the lower base value abnormality signal are externally output. As a result, it is possible to reduce the possibility that an abnormality in the base value will be overlooked.

(83) In the 84th to 87th embodiments, in addition to or instead of outputting the base value abnormality signal to the outside, the pachinko machine 10 may be configured to perform the base value abnormality notification that notifies the abnormality of the base value. Good. Specifically, in the 84th embodiment, the light emission of the display light emitting unit 53 is performed so that the base light abnormality flag 565 is set to "1" so as to emit light in a light emitting manner for notifying the abnormality of the base value. Take control. This allows the pachinko machine 10 to easily grasp the presence or absence of an abnormality in the base value. Further, in the 85th embodiment and the 87th embodiment, the base value exceeds the upper threshold of the normal base range based on that the upper base value abnormality flag 567 is set to "1". The light emission control of the display light emitting unit 53 is performed so as to emit light in a light emission mode for notifying that the base value is lower than the normal base range based on that the lower base value abnormality flag 568 is set to "1". The light emission control of the display light emitting unit 53 is performed so as to emit light in a light emitting mode that notifies an abnormal state of being below the threshold value. In the eighty-sixth embodiment, the base value abnormality flag 567 is set to "1" so that the base value exceeds the upper threshold value of the normal base range, and an abnormal state is emitted so as to emit light. The display light emitting section 53 is controlled to emit light. In addition, light emission is performed in a light emission mode for notifying an abnormal state in which the base value is below the lower first threshold value of the normal base range based on the fact that the lower first base value abnormality flag 571 is set to "1". As described above, the light emission control of the display light emitting unit 53 is performed, and the base value falls below the lower second threshold value of the normal base range based on the fact that the lower second base value abnormality flag 572 is set to "1". The light emission control of the display light emitting unit 53 is performed so that the light is emitted in the light emitting mode that notifies the abnormal state. This allows the pachinko machine 10 to easily grasp the presence or absence of an abnormality in the base value and the type of abnormality.

(84) In the first to fourteenth embodiments, the first to eighth parameters in the normal operation are calculated in S1404 of the display output process (FIG. 30), and the first to the eighth parameters in the open/close execution mode are calculated in step S1407. Instead of the configuration of calculating 18 parameters and calculating the 21st to 26th parameters in the high frequency support mode in step S1410, a configuration of calculating a payout rate may be used. As described above in the 89th embodiment, the payout rate is the ratio of the total payout number of the game balls to the total number of the game balls discharged from the game area PA in the entire game state. With the configuration for calculating the payout rate, the total number of game balls discharged from the gaming area PA in all the gaming states is suppressed while suppressing the number of parameters to be calculated, as compared with the configuration for calculating the parameters for each gaming state. It is possible to grasp an abnormality in the ratio of the total payout number of game balls to the number.

(85) In the 35th to 38th and 42nd to 97th embodiments, instead of the configuration of calculating the base value by using the values of the counters 231a to 231e of the normal counter area 231, the payout rate is changed. It may be configured to calculate. Specifically, the work area 223 for non-specific control is provided with the incoming ball number counter area 596 (FIG. 322) in the 89th embodiment, instead of the normal counter area 231. As described above in the 89th embodiment, the payout rate is the ratio of the total payout number of the game balls to the total number of the game balls discharged from the game area PA in the entire game state. The main CPU 63 calculates the payout rate using the values of the various counters 596a to 596e in the incoming ball number counter area 596. By the configuration for calculating the payout rate, the game area PA in the situation of the open/close execution mode and the high frequency support mode as well as the situation of neither the open/close execution mode by the jackpot result nor the high frequency support mode. It is possible to grasp the abnormality of the ratio of the total payout number of the game balls to the total number of the game balls discharged from.

(86) The payout rate in the entire unit calculation period for the latest four times calculated by the main CPU 63 in the 89th to 92nd embodiments, the payout rate in the first calculation period, the unit calculation period for the latest 10 times It is also possible to adopt a configuration in which the display for informing the overall ball output rate and the ball output rate in the second calculation period is not performed. The information of the payout rate is stored in the work area 223 for non-specific control after being calculated by the main CPU 63, and can be grasped. With the configuration in which the display for notifying the payout rate is not performed, the number of the notification display devices 591 to 595 can be reduced in the 89th to 91st embodiments.

(87) In the eighty-ninth to ninety-first embodiments, the first to fifth notification display devices 591 to 595 each have a payout rate in the last four unit calculation periods, a payout rate in a first calculation period, and a most recent time. Instead of displaying the payout rate in the entire unit calculation period for 10 times and the payout rate in the second calculation period, the payout rate may be output to an external device such as a hall computer. Good. In addition, in the 92nd embodiment, the first, third to fifth notification display devices 591, 593 to 595 display the payout rate in the first calculation period and the payout rate in the second calculation period. Instead of the configuration, the ball output rate may be output to an external device such as a hall computer. In the gaming hall, it is possible to check various payout rates with an external device without moving to the place where the pachinko machine 10 is installed, thereby reducing the burden of monitoring the payout rate by the manager of the game hall. be able to. In addition, the number of the notification display devices 591 to 595 is reduced in the 89th to 91st embodiments by configuring the notification display devices 591 to 595 not to display the various payout rates. be able to.

(88) In the above 89th to 91st embodiments, various payout rates on the 1st to 5th notification display devices 591 to 595 (the payout rate in the entire unit calculation period for the latest four times, in the first calculation period). In addition to the display of the payout rate, the payout rate in the entire unit calculation period for the last 10 times, and the payout rate in the second calculation period), in a situation where neither the open/close execution mode by the jackpot result nor the high frequency support mode is present. The base value, which is the ratio of the total payout number of game balls to the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA), may be displayed. Specifically, in the work area 223 for non-specific control, in addition to the incoming ball number counter area 596, the normal counter area 231 in the fifteenth embodiment is provided. As already described in the fifteenth embodiment, each of the counters 231a to 231e in the normal counter area 231 is in a state in which the front door frame 14 is in the closed state and is in either the open/close execution mode or the high frequency support mode. It is used to measure the number of game balls that have entered the target ball portions 24a, 31 to 34 in a non-problem situation. The base value is calculated based on the values stored in the counters 231a to 231e in the normal counter area 231.

Total payout of game balls for the total number of game balls discharged from the game area PA (that is, the total number of game balls supplied to the game area PA) in a situation where neither the open/close execution mode by the jackpot result nor the high frequency support mode is present. Even in the situation where the number ratio abnormality occurs, the total number of game balls to the total number of game balls discharged from the game area PA in all game states (that is, the total number of game balls supplied to the game area PA). A situation may occur in which the ratio of the number of payouts is within the normal range (first normal range or second normal range). On the other hand, by making it possible to grasp the base value in addition to various payout rates based on the displays of the first to fifth notification display devices 591 to 595, the first to fifth notification display devices 591 to Based on the display of 595, it is possible to grasp the abnormality of the base value that has occurred in a situation where the various payout rates are within the normal range (first normal range or second normal range).

(89) In the above 89th to 91st embodiments, the payout rate in the latest unit calculation period may be a display target in the first to fifth notification display devices 591 to 595. In the 89th embodiment, in the case where one or more payout rate data in the unit calculation period is stored in the first management buffer 601, the payout in the latest unit calculation period in the first management buffer 601 is set. The storage areas 601a to 601d in which the rate data is stored are display targets in the first to fifth notification display devices 591 to 595. The main CPU 63 specifies storage areas 601a to 601d corresponding to values obtained by subtracting 1 from the value of the first write pointer 603 as display targets. When the value obtained by subtracting 1 from the value of the first write pointer 603 is less than “0”, the main CPU 63 displays the third storage area 601d corresponding to the maximum value “3” of the first write pointer 603. Specify as the target. In the 90th embodiment, when the common management buffer 616 stores one or more payout rate data in the unit calculation period, the common management buffer 616 outputs the payout rate data in the most recent unit calculation period. The storage areas 616a to 616j in which is stored are to be displayed on the first to fifth notification display devices 591 to 595. The main CPU 63 specifies the storage areas 616a to 616j corresponding to the values obtained by subtracting 1 from the value of the common write pointer 617 as display targets. When the value obtained by subtracting 1 from the value of the common write pointer 617 is less than “0”, the main CPU 63 sets the ninth storage area 616j corresponding to the maximum value “9” of the common write pointer 617 as the display target. Identify. In the 91st embodiment described above, in the case where one or more payout rate data in the unit calculation period is stored in the common management counter area 621, the 0th payout rate counter 621a causes the first to fifth notifications. Display devices 591 to 595 are display targets. Whether or not there is an abnormality in the payout rate in the unit calculation period shorter than the first calculation period by making it possible to confirm the payout rate in the latest unit calculation period on the first to fifth notification display devices 591 to 595, It is also possible to grasp the degree of the abnormality. Accordingly, when an abnormality in the payout rate occurs, the abnormality can be grasped at an early stage.

In addition to the configuration of (89), the payout rate in the unit calculation period one time before and the payout rate in the unit calculation period two times before are displayed on the first to fifth notification display devices 591 to 595. It may be a target configuration. In the 89th embodiment, in a situation where three or more payout rate data in the unit calculation period are stored in the first management buffer 601, the first management buffer 601 outputs the latest payout ratio in the unit calculation period. The storage areas 601a to 601d in which the rate data, the payout rate data in the unit calculation period one time before, and the payout rate data in the unit calculation period two times before are stored are the first to fifth notification display devices 591. It becomes a display target in ˜595. The main CPU 63 stores the storage areas 601a to 601d corresponding to the value obtained by subtracting 1 from the value of the first write pointer 603, and the storage area corresponding to the value obtained by further subtracting 1 from the value of the first write pointer 603. The areas 601a to 601d and the storage areas 601a to 601d corresponding to the value obtained by further subtracting 1 from the value of the first write pointer 603 are specified as display targets. When the value obtained by subtracting 1 from the value of the first write pointer 603 is less than “0”, the main CPU 63 displays the third storage area 601d corresponding to the maximum value “3” of the first write pointer 603. Specify as the target. In the 90th embodiment, when the common management buffer 616 stores three or more payout rate data in the unit calculation period, the common management buffer 616 outputs the payout rate data in the most recent unit calculation period. The storage areas 616a to 616j in which the payout rate data in the unit calculation period one time before and the payout rate data in the unit calculation period two times before are stored are the first to fifth notification display devices 591 to 595. Will be displayed in. The main CPU 63 has storage areas 616a to 616j corresponding to values obtained by subtracting 1 from the value of the common write pointer 617 and storage areas 616a corresponding to values obtained by further subtracting 1 from the value of the common write pointer 617. To 616j and storage areas 616a to 616j corresponding to values obtained by further subtracting 1 from the value of the common write pointer 617 are specified as display targets. When the value obtained by subtracting 1 from the value of the common write pointer 617 is less than “0”, the main CPU 63 sets the ninth storage area 616j corresponding to the maximum value “9” of the common write pointer 617 as the display target. Identify. In the 91st embodiment, the 0th to 2nd payout rate counters 621a to 621c are set to the 1st when the common management counter area 621 stores three or more payout rate data in the unit calculation period. It becomes a display target in the first to fifth notification display devices 591 to 595. By making it possible to grasp the payout rate in the unit calculation period one time before and the payout ratio in the unit calculation period two times before on the first to fifth notification display devices 591 to 595, the unit calculation period It is possible to prevent the abnormality of the payout rate from being overlooked. Further, it is possible to reduce the frequency of confirming the payout rate during the unit calculation period, and to reduce the burden of monitoring the payout rate by the manager of the game hall.

(90) In the 89th to 92nd embodiments, when an abnormality occurs in which the payout rate in the first calculation period is out of the first normal range (41% to 149%), and the payout rate in the second calculation period. When an abnormality occurs outside the second normal range (51% to 133%), a signal for notifying the abnormality may be output to an external device such as a hall computer. An external device such as a hall computer makes it possible to grasp abnormalities in the payout rate in the first calculation period and abnormalities in the payout rate in the second calculation period, so that the manager of the game hall can monitor the payout rate. Can be reduced.

In addition, in the above configuration (90), a numerical range of 34% to 220% is set as a unit normal range that is a normal range of the payout rate during the unit calculation period, and the abnormal payout rate during the unit calculation period is set. It is also possible to adopt a configuration in which a signal for informing an abnormality in the payout rate is output to an external device such as a hall computer on the condition that the occurrence of is occurring. Specifically, when an abnormality occurs in which the payout rate in the first calculation period is out of the first normal range (41% to 149%), and when the payout rate in the second calculation period is the second normal range (51%). When an abnormality deviating from (-133%) occurs, a signal for notifying the abnormality is externally output on the condition that the abnormality in the payout rate in the latest unit calculation period has occurred. With this, it is possible to have a configuration in which an abnormality in the payout rate is still occurring and the signal for informing the abnormality in the payout rate is externally output only when prompt response is required. As a result, it is possible to reduce the frequency of externally outputting the signal for informing the abnormality of the payout rate, and to make it possible to grasp the case where a quick response is required, by an external device such as a hall computer.

(91) Abnormality in which the payout rate in the entire unit calculation period for the latest four times in the 89th to 91st embodiments is below the lower limit (41%) of the first normal range (41% to 149%), the first calculation Abnormality in which the payout rate in the period is below the lower limit (41%) of the first normal range (41% to 149%), and the payout rate in the entire unit calculation period for the last 10 times is in the second normal range (51% to 133%). ) Below the lower limit (51%), or an abnormality in which the payout rate in the second calculation period falls below the lower limit (51%) of the second normal range (51% to 133%), these abnormalities are generated. It is also possible to have a configuration in which a signal for informing is output to an external device such as a hall computer. Further, in the 92nd embodiment, the payout rate in the first calculation period is below the lower limit (41%) of the first normal range (41% to 149%), or the payout rate in the second calculation period is the second. When abnormalities below the lower limit (51%) of the two normal ranges (51% to 133%) occur, signals for notifying these abnormalities may be output to an external device such as a hall computer. An external device such as a hall computer can monitor anomalies where the payout rate is below the lower limit of the normal range (first normal range or second normal range), so that the manager of the game hall can monitor the payout rate. The burden can be reduced. Further, it is possible to give the manager of the game hall an opportunity to perform maintenance for adjusting the state of the nails 24b scrambled on the game board 24 of the pachinko machine 10.

(92) Abnormality in which the payout rate in the entire unit calculation period for the latest four times exceeds the upper limit (149%) of the first normal range (149% to 149%) in the 89th to 91st embodiments, the first calculation Abnormality in which the payout rate in the period exceeds the upper limit (149%) of the first normal range (149% to 149%), and the payout rate in the entire unit calculation period for the last 10 times is in the second normal range (133% to 133%). ) Above the upper limit (133%), or an abnormality in which the payout rate in the second calculation period exceeds the upper limit (133%) of the second normal range (133% to 133%), these abnormalities occur. It is also possible to have a configuration in which a signal for informing is output to an external device such as a hall computer. Further, in the 92nd embodiment, the payout rate in the first calculation period exceeds the upper limit (149%) of the first normal range (149% to 149%), or the payout rate in the second calculation period is the second. When abnormalities exceeding the upper limit (133%) of the two normal ranges (133% to 133%) occur, signals for notifying these abnormalities may be output to an external device such as a hall computer. An external device such as a hall computer can monitor anomalies where the payout rate exceeds the upper limit of the normal range (the first normal range or the second normal range), so that the manager of the game hall can monitor the payout rate. The burden can be reduced. Further, it is possible to give the manager of the game hall an opportunity to confirm whether or not there is an action that illegally raises the total payout number of game balls.

(93) Various payout rates in the 89th to 92nd embodiments (in the 89th to 91st embodiments, the payout rate in the entire unit calculation period for the last four times, the payout rate in the first calculation period, The payout rate in the entire unit calculation period for the last 10 times, or the payout rate in the second calculation period, in the 92nd embodiment, the payout rate in the first calculation period, or the payout rate in the second calculation period) is When an abnormality occurs that exceeds the upper limit of the normal range (the first normal range or the second normal range), an upper-side throw rate error signal is output to an external device such as a hall computer, and various throw rates are normal. It is also possible to adopt a configuration in which a lower-side payout rate abnormality signal is output to an external device such as a hall computer when an abnormality occurs that falls below the lower limit of the range (first normal range or second normal range). In this configuration, the upper-side ball-discharging rate abnormality signal and the lower-side ball-discharging rate abnormality signal are output in a manner that can be discriminated by an external device. As a result, the external device can recognize not only the presence/absence of an abnormality in each of the ball output rates but also the type of abnormality.

(94) Abnormality in which the payout rate in the entire unit calculation period for the latest four times in the 89th to 91st embodiments deviates from the first normal range (41% to 149%), and the payout rate in the first calculation period is Abnormalities outside the first normal range (41% to 149%), abnormalities in which the payout rate in the last 10 unit calculation periods is outside the second normal range (51% to 133%), or winnings in the second calculation period When an abnormality occurs in which the rate is out of the second normal range (51% to 133%), an abnormality signal for notifying the abnormality may be output to an external device such as a hall computer. Thereby, it is possible to grasp all of these abnormalities in the external device. In the 92nd embodiment, when an abnormality occurs in which the payout rate in the first calculation period is out of the first normal range, or when an abnormality in which the payout rate in the second calculation period is out of the second normal range occurs, these It is also possible to adopt a configuration in which an abnormality signal for notifying the abnormality is output to an external device such as a hall computer. This allows the external device to recognize both of these abnormalities.

(95) Abnormality in which the payout rate in the entire unit calculation period for the latest four times in the 89th to 91st embodiments deviates from the first normal range (41% to 149%), and the entire unit calculation period for the latest 10 times An abnormal signal for notifying the abnormality of the ball output rate is output to an external device such as a hall computer on the condition that both of the abnormality that the ball output rate in 2 is out of the second normal range (51% to 133%) have occurred. It may be configured. Specifically, in the work area 223 for non-specific control, it is possible for the main CPU 63 to know that the state in which the payout rate in the entire unit calculation period for the last four times is out of the first normal range has occurred. It is possible for the main CPU 63 to grasp that the occurrence of a state in which the ball output rate abnormality flag for 4 times and the ball output rate for the last 10 times of the unit calculation period are out of the second normal range has occurred. A ball rate abnormality flag is provided. The main CPU 63 sends an abnormal signal to an external device such as a hall computer on condition that both of the four-ball-deliver-rate abnormality flag and the ten-ball-deposit-rate-abnormal flag are set to "1". Output. As described above, both the abnormality in which the payout rate in the entire unit calculation period for the last four times is out of the first normal range and the abnormality in which the payout rate in the entire unit calculation period for the latest ten times is outside the second normal range By configuring to output the abnormal signal externally on the condition that it has occurred, when the abnormal signal is confirmed by an external device, it is possible to grasp that the degree of abnormalities in the ball throwing rate is serious, and take prompt action. Can be encouraged.

Further, in the 92nd embodiment, both the abnormality in which the payout rate in the first calculation period is out of the first normal range and the abnormality in which the payout rate in the second calculation period is out of the second normal range have occurred. It is also possible to adopt a configuration in which an abnormal signal for notifying an abnormality in the payout rate is output to an external device such as a hall computer under the above condition. Specifically, in the work area 223 for non-specific control, it is possible for the main CPU 63 to recognize that the state in which the payout rate is out of the first normal range has occurred in the first calculation period. A payout rate abnormality flag and a second payout rate flag that allow the main CPU 63 to know that a state where the payout rate in the second calculation period is out of the second normal range have been provided. There is. The main CPU 63 sends an error signal to an external device such as a hall computer on condition that both the first and second ball output rate abnormality flags are set to "1". Output. As described above, the abnormality signal is generated under the condition that both the abnormality in which the payout rate in the first calculation period is out of the first normal range and the abnormality in which the payout rate in the second calculation period is out of the second normal range have occurred. When the abnormal signal is confirmed by the external device, it is possible to grasp that the abnormal degree of the ball output rate is serious, and prompt action can be promoted.

(96) Instead of the configuration in which a plurality of payout rate data in the unit calculation period is stored in the 89th to 92nd embodiments, a plurality of information on the total payout number of the final game balls in the unit calculation period is stored. May be configured. Specifically, in the calculation process of the total number of discharged balls in step SL110 of the check process (FIG. 325), it is stored in the various counters 596a to 596e in the number-of-balls-counter area 596 as already described in the 89th embodiment. By calculating the total value of the values, the total number of game balls discharged from the game area PA (total discharged number) in all game states is calculated. After that, when the calculated total discharge number is the unit reference number of 6000 or more, that is, when the unit calculation period ends, the final total payout number in the unit calculation period ended this time is calculated. When the values of the various counters 596a to 596e of the incoming ball number counter area 596 are set to K101 to K105, the final total payout number of the game balls in the unit calculation period is in the incoming ball number counter area 596 at the end of the unit calculation period. It is calculated by the following formula using the values stored in the various counters 596a to 596e.
-Total payout number of game balls: K101 x "number of prize balls for winning in the general winning opening 31" + K102 x "number of prize balls for winning in the special electric prize winning device 32" + K103 x "for winning in the first working opening 33" “Number of prize balls”+K104דnumber of prize balls for winning in the second operation port 34”.

After that, information on the final total payout number in the unit calculation period calculated by the above formula (hereinafter, also referred to as total payout number data in the unit calculation period) is stored. In the 89th and 92nd embodiments, the total payout amount data in the unit calculation period is stored in one of the storage areas 601a to 601d of the first management buffer 601 corresponding to the value of the first write pointer 603, and in the second It is stored in any of the storage areas 602a to 602j of the second management buffer 602 corresponding to the value of the write pointer 604. In the first payout rate calculation processing in step SL208 of the payout rate storage processing (FIG. 326), after the calculation area 598 is cleared to “0”, the unit stored in the 0th storage area 601a of the first management buffer 601. The total payout amount data in the calculation period is set in the calculation area 598. After that, three total payout numbers in each unit calculation period for three times stored in the first to third storage areas 601b to 601d of the first management buffer 601 are added to the value of the calculation area 598. As a result, the total payout number in the entire unit calculation period for the latest four times (the total value of the four total payout numbers in each unit calculation period for the latest four times) is set in the calculation area 598. Then, the value in the calculation area 598 is divided by "240". As a result, the unit for the latest four times obtained by dividing the total payout number in the entire unit calculation period for the latest four times by “24000” which is four times the unit reference number (specifically, 6000) and multiplying by 100 The payout rate for the entire calculation period is stored in the calculation area 598. After that, the ball output rate data for the entire calculated latest four unit calculation periods is stored in the first unit update area 606a. In the second payout rate calculation processing in step SL220 of the payout rate storage processing (FIG. 326), after the calculation area 598 is cleared to “0”, it is stored in the 0th storage area 602a of the second management buffer 602. The total payout amount data in the unit calculation period that is present is set in the calculation area 598. Then, nine total payout numbers in each of the nine unit calculation periods stored in the first to ninth storage areas 602b to 602j of the second management buffer 602 are added to the value of the calculation area 598. As a result, the total payout number in the entire unit calculation period for the last 10 times (the total value of the 10 total payout numbers in each unit calculation period for the latest 10 times) is set in the calculation area 598. Then, the value in the calculation area 598 is divided by "600". As a result, the unit for the latest 10 times obtained by dividing the total payout number in the entire unit calculation period for the latest 10 times by “60000” which is 10 times the unit reference number (specifically, 6000) and multiplying by 100 The payout rate for the entire calculation period is stored in the calculation area 598. After that, the ball output rate data for the entire calculated latest 10 unit calculation periods is stored in the second unit update area 607a.

In the 90th embodiment, the total payout amount data in the unit calculation period calculated by the above formula is stored in any of the storage areas 616a to 616j of the common management buffer 616 corresponding to the value of the common write pointer 617. In the first payout rate calculation processing (FIG. 332), the calculation area 598 is cleared to “0”. After that, the value of the common write pointer 617 is decremented by 1, and the value of the subtraction number counter 619 is incremented by "1". Similar to the 90th embodiment, when the value of the common write pointer 617 after subtraction is less than “0”, the common write pointer 617 is set to the maximum value “9”. After that, the total payout amount data in the unit calculation period stored in any of the storage areas 616a to 616j of the common management buffer 616 corresponding to the value after subtraction of 1 is set in the calculation area 598. After that, the value of the common write pointer 617 is decremented by 1 and the value of the subtraction number counter 619 is incremented by 1 until the value of the subtraction count counter 619 becomes “4”, and the value of the common write pointer 617 after the subtraction by 1 is obtained. A series of processes for adding the total payout amount in the unit calculation period stored in the corresponding storage areas 616a to 616j to the calculation area 598 is repeated. As a result, the total payout number in the entire unit calculation period for the latest four times (the total value of the four total payout numbers in each unit calculation period for the latest four times) is set in the calculation area 598. Then, the value in the calculation area 598 is divided by "240". As a result, the unit for the latest four times obtained by dividing the total payout number in the entire unit calculation period for the latest four times by “24000” which is four times the unit reference number (specifically, 6000) and multiplying by 100 The payout rate for the entire calculation period is stored in the calculation area 598. After that, the calculated payout rate for the last four unit calculation periods is stored in the first unit update area 606a. In the second payout rate calculation processing in step SL518 of the payout rate storage processing (FIG. 331), after the calculation area 598 is cleared to “0”, the unit calculation stored in the 0th storage area 616a of the common management buffer 616 is calculated. The total payout amount data for the period is set in the calculation area 598. Then, nine total payout numbers in each unit calculation period for nine times stored in the first to ninth storage areas 616b to 616j of the common management buffer 616 are added to the value of the calculation area 598. As a result, the total payout number in the entire unit calculation period for the last 10 times (the total value of the 10 total payout numbers in each unit calculation period for the latest 10 times) is set in the calculation area 598. Then, the value in the calculation area 598 is divided by "600". As a result, the unit for the latest 10 times obtained by dividing the total payout number in the entire unit calculation period for the latest 10 times by “60000” which is 10 times the unit reference number (specifically, 6000) and multiplying by 100 The payout rate for the entire calculation period is stored in the calculation area 598. After that, the ball output rate data for the entire calculated latest 10 unit calculation periods is stored in the second unit update area 607a.

In the 91st embodiment, the total payout amount data in the unit calculation period calculated by the above formula is executed after the data shift process of the common management counter area 621 is executed in step SL701 of the payout rate storage process (FIG. 334). Is stored in the 0th payout rate counter 621a in the common management counter area 621. In the first payout rate calculation processing in step SL708 of the payout rate storage processing (FIG. 334), after the calculation area 598 is cleared to “0”, it is stored in the 0th payout rate counter 621a in the common management counter area 621. The total payout amount data in the unit calculation period that is present is set in the calculation area 598. After that, to the value of the calculation area 598, three total payout numbers in each unit calculation period for three times stored in the first to third payout rate counters 621b to 612d of the common management counter area 621 are added. To do. As a result, the unit for the latest four times is obtained by dividing the total payout number in the entire unit calculation period for the latest four times by "24000" which is four times the unit reference number (specifically, 6000) and multiplying by 100. The ball output rate data for the entire calculation period is stored in the calculation area 598. After that, the ball output rate data for the entire calculated latest four unit calculation periods is stored in the first unit update area 606a. In the second payout rate calculation processing in step SL716 of the payout rate storage processing (FIG. 334), after the calculation area 598 is cleared to “0”, it is stored in the 0th payout rate counter 621a in the common management counter area 621. The total payout amount data in the unit calculation period that is present is set in the calculation area 598. After that, to the value of the calculation area 598, nine total payout numbers in each unit calculation period for nine times stored in the first to ninth payout rate counters 621b to 612j of the common management counter area 621 are added. To do. As a result, the total payout number in the entire unit calculation period for the last 10 times (the total value of the 10 total payout numbers in each unit calculation period for the latest 10 times) is set in the calculation area 598. Then, the value in the calculation area 598 is divided by "600". As a result, the unit for the latest 10 times obtained by dividing the total payout number in the entire unit calculation period for the latest 10 times by “60000” which is 10 times the unit reference number (specifically, 6000) and multiplying by 100 The payout rate for the entire calculation period is stored in the calculation area 598. After that, the ball output rate data for the entire calculated latest 10 unit calculation periods is stored in the second unit update area 607a.

In this way, instead of the payout rate data in the unit calculation period, a plurality of total payout amount data in the unit calculation period are stored, and the unit for the latest four times is calculated based on the plurality of total payout amount data in each of the plurality of unit calculation periods. A payout rate in the unit calculation period to be stored each time the unit calculation period ends, by calculating the payout rate in the entire calculation period and the payout rate in the entire latest 10 unit calculation periods. It is possible to omit the process of calculating the rate. In addition, the number of divisions performed in the process of calculating the payout rate in the entire unit calculation period for the latest 4 times and the payout rate in the entire unit calculation period for the latest 10 times is set to 1 The accuracy can be increased.

(97) In the 89th to 92nd embodiments, each of the first to fifth notification display devices 591 to 595 has a second decimal place in the range of "0.00" to "9.99". It may be configured to be displayed as numerical information up to. In the configuration, various payout rates are “0.00” to “9” by dividing the total payout number of game balls in all the gaming states by the total number of game balls discharged from the game area PA of the pachinko machine 10. It is calculated as 3-digit numerical information in the range of ".99". The third notification display device, like the first notification display device 591 in the 89th embodiment, has eight display segments. Of the eight display segments in the third notification display device, seven display segments are rod-shaped light emitting regions having the same shape and the same size, and are arranged so as to generate the shape of "8". ing. On the other hand, one display segment is a circular light emitting region, and is provided at the lower right position with respect to the seven display segments arranged in the shape of "8". Thus, the decimal point can be displayed in addition to the one-digit number on the third notification display device. The third notification display device displays the one-digit number of the payout rate and the decimal point, and the fourth notification display device 594 displays the one-digit number of the payout rate. , The fifth notification display device 595 displays the number on the second decimal place of the payout rate. Even with this configuration, it is possible to grasp the 3-digit payout rate based on the displays of the third to fifth notification display devices 593 to 595.

(98) In the 89th to 91st embodiments, among the various areas 606a to 606d of the first display target area 606 and the various areas 607a to 607d of the second display target area 607 in the first notification display device 591. A display indicating which of the payout rates is being notified is performed, and the first display target area 606 is displayed on the first to fifth notification display devices 591 to 595 on the second notification display device 592. The display indicating that the payout rate is stored in the display area and the display indicating that the payout rate stored in the second display target area 607 is displayed are displayed. It may be configured to be opened. Specifically, in a situation in which the payout rate of the first unit update area 606a has been notified, “0d” is displayed on the first and second notification display devices 591 and 592, and the second unit update is performed. In a situation where the payout rate of the area 607a is informed, "0d." is displayed on the first and second informing display devices 591 and 592. In a situation in which the payout rate of the area 606b closest to the first calculation period is informed, "1d" is displayed on the first and second notification display devices 591 and 592, and the area closest to the second calculation period is displayed. In a situation where the payout rate of 607b is informed, "1d." is displayed on the first and second informing display devices 591 and 592. In a situation in which the payout rate of the first history area 606c in the first calculation period is informed, “2d” is displayed on the first and second notification display devices 591 and 592, and the second calculation period "2d." is displayed on the first and second notification display devices 591 and 592 in a situation where the payout rate of the first history area 607c is notified. In the situation where the payout rate of the second history area 606d in the first calculation period is informed, "3d" is displayed on the first and second informing display devices 591, 592, and In a situation where the payout rate of the second history area 607d is informed, "3d." is displayed on the first and second informing display devices 591 and 592. As described above, by configuring the second notification display device 592 to display “d” or “d.”, the first notification display device 591 has a number of “0” to “3”. It is possible to avoid that the display of the number continues from the display of the three numbers on the third to fifth notification display devices 593 to 595 even if the display of “3” is performed. As a result, the display of various payout rates on the first to fifth notification display devices 591 to 595 can be made easy to understand, and the possibility of misidentification of the payout rate can be reduced.

(99) The base value may be calculated instead of the structure for calculating various payout rates in the 89th to 91st embodiments. Specifically, the work area 223 for non-specific control is provided with a normal counter area 231 (FIG. 72) instead of the incoming ball number counter area 596 (FIG. 322) as in the 35th embodiment. Has been. As already described in the thirty-fifth embodiment, the base value is the total number of game balls discharged from the game area PA in the situation where neither the open/close execution mode by the big hit result nor the high frequency support mode (that is, the game area PA). It is the ratio of the total payout number of game balls to the total number of game balls supplied to. In the work area 223 for non-specific control, a current base value area is provided instead of the current ball output rate area 599. Each time the check process (FIG. 325) is executed, the current base value is calculated using the values stored in the various counters 231a to 231e of the normal counter area 231. Currently stored in the base value area. In this configuration, unit calculation is performed when the total number of game balls discharged from the game area PA reaches 6000, which is the unit reference number for base, in a situation where neither the open/close execution mode due to the big hit result nor the high frequency support mode is reached. The period ends. When the unit calculation period ends, the current base value area stores the final base value information in the unit calculation period ended this time (hereinafter, also referred to as base value data in the unit calculation period). ..

In the 89th embodiment, when the unit calculation period ends, the base value data in the unit calculation period stored in the current base value acquisition area corresponds to the value of the first write pointer 603 in the first management buffer 601. It is stored in any of the storage areas 601a to 601d and in any of the storage areas 602a to 602j of the second management buffer 602 corresponding to the value of the second write pointer 604. When the base value is written in the first management buffer 601 during the unit calculation period, the value of the first write pointer 603 is incremented by 1 and updated, and at the same time, the second management buffer for the base value during the unit calculation period is updated. When writing to 602, the value of the second write pointer 604 is incremented by 1 and updated. When the base values in the unit calculation period are stored in the first management buffer 601 and the second management buffer 602, the main CPU 63 has four storage areas 601a to 601d of the first management buffer 601. The base value in the entire unit calculation period for the latest four times is calculated by dividing the total value of the base values of 4 by "4". Then, the calculated base values for the latest four unit calculation periods are stored in the first unit update area 606a. When the base values in the unit calculation period are stored in the first management buffer 601 and the second management buffer 602, the main CPU 63 is stored in the ten storage areas 602a to 602j of the second management buffer 602. By dividing the total value of 10 base values by “10”, the base value in the entire unit calculation period for the last 10 times is calculated. Then, the calculated base value for the last ten unit calculation periods is stored in the second unit update area 607a.

In the 90th embodiment, when the unit calculation period ends, the base value data in the unit calculation period currently stored in the base value area corresponds to the value of the common write pointer 617 in one of the common management buffers 616. It is stored in the storage areas 616a to 616j. When the base value is written in the common management buffer 616 in the unit calculation period, the value of the common write pointer 617 is incremented by 1 and updated. When the base value in the unit calculation period is stored in the common management buffer 616, the main CPU 63, based on the value of the common write pointer 617, the four base values in the unit management period for the last four times in the common management buffer 616. The storage areas 616a to 616j in which is stored are specified. Then, by dividing the total value of the four base values stored in the specified storage areas 616a to 616j by "4", the base value in the entire unit calculation period for the latest four times is calculated. Then, the calculated base values for the latest four unit calculation periods are stored in the first unit update area 606a. When the base value in the unit calculation period is stored in the common management buffer 616, the main CPU 63 causes the main CPU 63 to sum the 10 base values stored in the 10 storage areas 616a to 616j of the common management buffer 616. Is divided by “10” to calculate the base value in the entire unit calculation period for the last 10 times. Then, the calculated base value for the last ten unit calculation periods is stored in the second unit update area 607a.

In the 91st embodiment, 0th to 9th base value counters are provided in place of the 0th to 9th payout rate counters 621a to 621j. When the unit calculation period ends, the data shift process of the common management counter area 621 (step SL701 of the payout rate storage process (FIG. 334)) is executed. In the data shift processing, the information on the payout rate stored in the 0th to 9th base value counters in the common management counter area 621 is changed to the 8th base value counter→the 9th base value counter, the 7th base value counter→the 7th base value counter. 8 base value counter, 6th base value counter → 7th base value counter, 5th base value counter → 6th base value counter, 4th base value counter → 5th base value counter, 3rd base value counter → 4th base The value counter, the second base value counter→the third base value counter, the first base value counter→the second base value counter, the 0th base value counter→the first base value counter are shifted in this order. As a result, the base value in the unit calculation period nine times before is stored in the ninth base value counter, the base value in the unit calculation period eight times before is stored in the eighth base value counter, and the unit calculation period seven times ago. Is stored in the seventh base value counter, the base value in the unit calculation period six times before is stored in the sixth base value counter, and the base value in the unit calculation period five times before is stored in the fifth base value counter. The base value in the unit calculation period four times before is stored in the fourth base value counter, the base value in the unit calculation period three times before is stored in the third base value counter, and the unit calculation period two times before The base value in is stored in the second base value counter, and the base value in the previous unit calculation period is stored in the first base value counter. In the data shift processing of the common management counter area 621, the value of the 0th base value counter is cleared to “0”. After that, the base value data in the unit calculation period stored in the current base value area is stored in the 0th base value counter of the common management counter area 621. When the base value in the unit calculation period is stored in the common management counter area 621, the main CPU 63 divides the total value of the four base values stored in the 0th to 3rd base value counters by “4”. By doing so, the base value in the entire unit calculation period for the latest four times is calculated. Then, the calculated base values for the latest four unit calculation periods are stored in the first unit update area 606a. When the base value in the unit calculation period is stored in the common management counter area 621, the main CPU 63 determines that the total value of the 10 base values stored in the 10 base value counters of the common management counter area 621 is “ The base value in the entire unit calculation period for the latest 10 times is calculated by dividing by 10”. Then, the calculated base value for the last ten unit calculation periods is stored in the second unit update area 607a.

(100) In the 93rd to 97th embodiments, the operation unit operated to display the total number information on the first to fourth notification display devices 201 to 204 is limited to the reset button 68c. Alternatively, the update button 68b may be used. Specifically, when the update button 68b is operated in a situation where the latest base values are displayed on the first to fourth notification display devices 201 to 204, the first to fourth notification display devices 201 are displayed. It is also possible to adopt a configuration in which the total number information is displayed at 204.

(101) In the 93rd to 97th embodiments, when the pressing operation of the reset button 68c is performed in the situation where the most recent base value is displayed on the first to fourth notification display devices 201 to 204. Instead of the configuration in which the total number information is displayed for the display continuation period (specifically, 5 seconds) on the first to fourth notification display devices 201 to 204, the pressing operation of the reset button 68c is started. The total number of pieces of information may be continuously displayed for a period from when the pressing operation ends until the pressing operation ends. Specifically, one of the base values stored in the current area 311, the first history area 312, the second history area 313, and the third history area 314 in the first to fourth notification display devices 201 to 204. When the pressing operation of the reset button 68c is started in the situation where is displayed, the display data of the total number information corresponding to the total number data stored in the total number area 631 until the pressing operation is finished. Is set in the display target setting area 276. As already described in the 93rd embodiment, the display data of the total number information includes display data for causing the first notification display device 201 to perform a display corresponding to the tens place digit in the total number data, Display data for causing the second notification display device 202 to perform a display corresponding to the thousands digit in the total number data, and a display corresponding to the hundreds digit in the total number data for the third notification display device. The display data for causing 203 to perform, and the display data for causing the fourth notification display device 204 to perform the display corresponding to the tens digit in the total number data are included. The manager of the game hall continues pressing the reset button 68c until the total number information is grasped, and terminates the pressing operation of the reset button 68c at the stage when the total number information is grasped. It is possible to restart the display of the base value on the first to fourth notification display devices 201 to 204.

(102) In the 93rd to 97th embodiments, the total number information may be displayed on the first to fourth notification display devices 201 to 204 even if the reset button 68c is not pressed. .. Specifically, in a situation where the set value is not confirmed and the set value is not updated, the notification target on the first to fourth notification display devices 201 to 204 is the base value of the current area 311 → total number information → 1 history area 312 base value→second history area 313 base value→third history area 314 base value are updated in this order, and after the display of the third history area 314 base value ends, the notification target is the current area. The configuration may be such that the base value of 311 is returned to, and in the situation where the setting value is not confirmed and the setting value is not updated, the notification target in the first to fourth notification display devices 201 to 204 is the total number information→the current area. The base value of 311→the base value of the first history area 312→the base value of the second history area 313→the base value of the third history area 314 are updated in this order, and the display of the base value of the third history area 314 is completed. The notification target may be returned to the total number information later. With these configurations, it is possible to grasp the total number information on the first to fourth notification display devices 201 to 204 without requiring the operation of the reset button 68c, and at the same time, regarding the latest base value. The degree of convergence can be grasped. In the configuration in which the total number information is displayed after the display of the most recent base value in the current area 311 is completed, the current base value is grasped, and then the most recent base value is displayed based on the display of the total number information. The degree of convergence can be grasped. Further, in the configuration in which the latest base value is displayed in the current area 311 after the display of the total number information is completed, it is possible to grasp the latest base value while grasping the degree of convergence of the latest base value. can do.

(103) In the 93rd to 97th embodiments, in addition to the 1st to 4th display devices 201 to 204, a 5th display device for displaying the digit of one digit in the total number data is provided. The main control board 61 may be provided. As already described in the 93rd Embodiment, the total number data is 2-byte numerical value information indicating any numerical value of “0” to “65535”. When the pressing operation of the reset button 68c is performed in the situation where the most recent base value is displayed on the first to fourth notification display devices 201 to 204, the first notification display device 201 may have a problem in the total number data. The second digit display device 202 displays the thousands digit in the total number data, and the third bulletin display device 203 displays the hundreds digit in the total number data. The tenth digit in the total number data is displayed on the fourth notification display device 204, and the ones digit in the total number data is displayed on the fifth notification display device. Accordingly, it is possible to grasp the entire total number data (five-digit number) based on the displays of the first to fourth notification display devices 201 to 204 and the fifth notification display device.

(104) In the 93rd to 97th embodiments, when the display corresponding to the total number data is performed on the first to fourth notification display devices 201 to 204, the total is displayed on the first notification display device 201. It may be configured to display that the display corresponding to the number data is being performed. Specifically, when the display corresponding to the total number data is performed on the first to fourth notification display devices 201 to 204, the character “s” is displayed on the first notification display device 201. When a display other than the display corresponding to the total number data is displayed on the first to fourth notification display devices 201 to 204, the character “s” is not displayed on the first notification display device 201. .. Thereby, by confirming that the character "s" is displayed on the first notification display device 201, the manager of the gaming hall displays the total on the first to fourth notification display devices 201 to 204. It becomes possible to understand that the display corresponding to the number data is being performed. In this configuration, when the reset button 68c is pressed in a situation where the latest base values are displayed on the first to fourth notification display devices 201 to 204, “s” is displayed on the first notification display device 201. Is displayed, the second notification display device 202 displays the tens digit of the total number data, and the third notification display device 203 displays the thousands digit of the total number data. The hundreds digit in the total number data is displayed on the 4 notification display device 204. Accordingly, it is possible to easily grasp that the display corresponding to the total number data is being performed on the first to fourth notification display devices 201 to 204, and to grasp the upper three digits of the total number data. Can be

(105) In the 93rd to 97th embodiments, the first timer interrupt processing (FIG. 338 in the 93rd and 96th embodiments, FIG. 350 in the 94th embodiment, and FIG. 353 in the 95th embodiment). When either the second timer interrupt process (FIG. 346) is activated, a program such as a DI instruction is automatically executed to automatically interrupt the first timer interrupt process and the second timer interrupt process. It may be configured. In the configuration, in the first step in the first timer interrupt processing, "EI" is set as the "EI", and the EI instruction switches from the prohibited state to the permitted state to the first timer interrupt process and the second timer interrupt process. Settings for. As a result, it becomes possible to newly execute the first timer interrupt process and the second timer interrupt process. Therefore, when the second interrupt period (specifically, 2 milliseconds) has elapsed during execution of the first timer interrupt process, the second timer interrupt process can be interrupted and activated. On the other hand, in the second timer interrupt process, the process of switching the generation of the first timer interrupt process and the second timer interrupt process from the prohibited state to the permitted state is not executed. As a result, it is possible to prevent the first timer interrupt process from being interrupted and activated during execution of the second timer interrupt process. As already described in the thirty-third embodiment, the first to fifth display circuits 261 to 265 can store and hold the provided display data for a predetermined period (for example, 16 milliseconds). The display data gradually approaches the state of all "0" when the period elapses. In the configuration, the start of the second timer interrupt process is prevented from being delayed, and the first timer interrupt process is prevented from being interrupted and started during the execution of the second timer interrupt process. It is possible to prevent flicker from occurring in the display on 37a, the special figure reservation display section 37b, the general figure display section 38a, the general figure reservation display section 38b, and the first to fourth notification display devices 201 to 204. ..

(106) In the 93rd to 97th embodiments described above, there are two types of calculation periods as the calculation period of the base value, and the first to fourth notification display devices 201 to 204 total the respective calculation periods. The number information may be displayed. Specifically, as the base value calculation period, the total number of game balls discharged from the game area PA in a situation where neither the open/close execution mode due to the big hit result nor the high frequency support mode (that is, supplied to the game area PA). Every time the total number of game balls reaches 24000, one calculation period ends and the next calculation period starts, and neither the opening/closing execution mode or the high-frequency support mode depending on the jackpot result. Every time the total number of game balls discharged from the game area PA in the situation (that is, the total number of game balls supplied to the game area PA) reaches 60000, one calculation period ends and the next calculation period starts. And a second calculation period that is set. In the pachinko machine 10, a maximum of 100 game balls are fired per minute, so 24000 is the maximum number of shots in 4 hours and 60000 is the maximum number of shots in 10 hours.

The work area 223 for non-specific control is provided with a normal counter area for the first calculation period and a normal counter area for the second calculation period. Similar to the normal counter area 231 in the 93rd embodiment described above, these normal counter areas include a normal general prize winning counter, a normal special electric prize winning counter, a normal first operation counter, and a normal ordinary winning area. A second actuation counter and a normal out counter are provided. In the situation where neither the open/close execution mode by the jackpot result nor the high frequency support mode is available, when one game ball enters the general winning opening 31, the normal general winning counter in the above two normal counter areas When the value is incremented by 1 and one gaming ball enters the special electricity winning device 32, the value of the normal special electricity winning counter in the above two normal counter areas is incremented by 1, and the first working opening 33 is added. When one game ball enters, the value of the first normal operation counter in the above two normal counter areas is incremented by 1, and when one game ball enters the second operation port 34 The value of the normal second operation counter in the above two normal counter areas is incremented by 1, and when one game ball enters the out port 24a, the normal in the above two normal counter areas 1 is added to the value of the out counter.

The first calculation period ends when the total value of the values of the various areas in the normal counter area for the first calculation period reaches 24000. In this case, the value of each area in the normal counter area for the first calculation period is cleared to "0", and the next first calculation period is started. The second calculation period ends when the total value of the values in the various areas in the normal counter area for the second calculation period reaches 60,000. In this case, the value of each area in the normal counter area for the second calculation period is cleared to "0", and the next second calculation period is started.

In the calculation result storage area 234 of the work area 223 for non-specific control, the current area of the first calculation period in which the most recent base value in the first calculation period is stored, and the final area in the first calculation period one time before. History area of the first calculation period in which the base value is stored, a second history area of the first calculation period in which the final base value in the first calculation period two times before is stored, and three times before The third history area of the first calculation period in which the final base value in the first calculation period is stored, the current area in the second calculation period in which the latest base value in the second calculation period is stored, and In the first history area of the second calculation period in which the final base value in the previous second calculation period is stored, and in the second calculation period in which the final base value in the second calculation period two times before is stored. A second history area and a third history area of the second calculation period in which the final base value in the second calculation period three times before is stored are provided. In the first to fourth notification display devices 201 to 204, the display target is the current area of the first calculation period → the first history area of the first calculation period every time 5 seconds, which is the display duration of the base value, elapses. →second history area of first calculation period→third history area of first calculation period→current area of second calculation period→first history area of second calculation period→second history area of second calculation period→second Switching is performed according to a predetermined display order of the third history area of two calculation periods. Then, after the base value stored in the third history area of the second calculation period is displayed for the display continuation period (specifically, 5 seconds), the display target is the current area of the first calculation period. Return to.

The work area 223 for non-specific control is provided with a total number area of the first calculation period and a total number area of the second calculation period. The total number area of the first calculation period is the total number of game balls discharged from the game area PA in the situation where neither the open/close execution mode by the big hit result nor the high frequency support mode is present in the first calculation period of the current state (that is, the game). It is a counter in which the total number data of the first calculation period, which is numerical information indicating the total number of gaming balls supplied to the area PA, is stored. The main CPU 63 calculates the total number data of the first calculation period by summing the values of various counters in the normal counter area for the first calculation period. The total number data in the first calculation period is 2-byte numerical value information indicating any numerical value of “0” to “65535”. The total number area of the second calculation period is the total number of game balls discharged from the game area PA in the current second calculation period in neither the open/close execution mode due to the big hit result nor the high frequency support mode (that is, the game ball). It is a counter in which the total number data of the second calculation period, which is numerical information indicating the total number of gaming balls supplied to the area PA, is stored. The main CPU 63 calculates the total number data of the second calculation period by summing the values of various counters in the normal counter area for the second calculation period. The total number data in the second calculation period is 2-byte numerical value information indicating any numerical value of “0” to “65535”.

When the operation of the reset button 68c is performed in a situation in which the most recent base value in the first calculation period is displayed on the first to fourth notification display devices 201 to 204, the main CPU 63 displays the first calculation period. The display data of the total number information in the first calculation period corresponding to the total number data of the first calculation period stored in the total number area is generated, and the display data of the total number information in the first calculation period is non-specifically controlled. The work area 223 for display is set in the display target setting area 276. The display data of the total number information in the first calculation period includes display data for causing the first notification display device 201 to perform a display corresponding to a digit of tens of thousands in the total number data in the first calculation period. Corresponding to display data for causing the second notification display device 202 to perform display corresponding to the thousands digit in the total number data of the calculation period and the hundreds digit in the total number data of the first calculation period. Display data for causing the third notification display device 203 to perform display, and display for causing the fourth notification display device 204 to perform display corresponding to the tens digit in the total number data of the first calculation period. Including data and.

In the second timer interrupt process (FIG. 346), the display data of the total number information in the first calculation period stored in the display target setting area 276 is read, and the read total number information in the first calculation period is read. Display data is stored in the fifth display data buffer 275 (FIG. 120(a)). The display data of the total number information in the first calculation period stored in the fifth display data buffer 275 is transmitted to the display IC 266 (FIG. 119), and the display data of the total number information in the first calculation period is displayed by the display IC 266. By being provided to the fifth display circuit 265 (FIG. 119), the total number information in the first calculation period is displayed on the first to fourth notification display devices 201 to 204 (FIG. 53). In the display of the total number information in the first calculation period, the upper four digits of the total number data in the first calculation period are displayed on the first to fourth notification display devices 201 to 204. Based on the display, the game hall manager can grasp the degree of convergence of the latest base value in the first calculation period.

When the operation of the reset button 68c is performed in a situation in which the most recent base value in the second calculation period is displayed on the first to fourth notification display devices 201 to 204, the main CPU 63 displays the second calculation period. The display data of the total number information in the second calculation period corresponding to the total number data of the second calculation period stored in the total number area is generated, and the display data of the total number information in the second calculation period is non-specifically controlled. The work area 223 for display is set in the display target setting area 276. The display data of the total number information in the second calculation period includes display data for causing the first notification display device 201 to perform a display corresponding to the digit of tens of thousands in the total number data in the second calculation period. Corresponding to display data for causing the second notification display device 202 to perform a display corresponding to the thousands digit in the total number data of the calculation period and the hundreds digit in the total number data of the second calculation period. Display data for causing the third notification display device 203 to perform display, and display for causing the fourth notification display device 204 to perform display corresponding to the tens digit in the total number data of the second calculation period. Including data and.

In the second timer interrupt process (FIG. 346), the display data of the total number information in the second calculation period stored in the display target setting area 276 is read, and the read total number information in the second calculation period is read. Display data is stored in the fifth display data buffer 275 (FIG. 120(a)). The display data of the total number information in the second calculation period stored in the fifth display data buffer 275 is transmitted to the display IC 266 (FIG. 119), and the display data of the total number information in the second calculation period is displayed from the display IC 266. By being provided to the fifth display circuit 265 (FIG. 119), the total number information in the second calculation period is displayed on the first to fourth notification display devices 201 to 204 (FIG. 53). In the display of the total number information in the second calculation period, the upper four digits of the total number data in the second calculation period are displayed on the first to fourth notification display devices 201 to 204. The manager of the game hall can grasp the degree of convergence of the latest base value in the second calculation period based on the display.

As described above with reference to FIGS. 127(a) to 127(d) in the thirty-fifth embodiment, each of the first to fourth notification display devices 201 to 204 has eight display segments 321 to 324. have. Of the eight display segments 321-324, the seven display segments 321-324 are all rod-shaped light emitting regions having the same shape and size, and are arranged so as to generate a "8" shape. Has been done. On the other hand, one display segment 321 to 324 is a circular light emitting region and is located at the lower right position with respect to the seven display segments 321 to 324 arranged in the shape of "8". It is provided. When the total number information in the first calculation period is displayed on the first to fourth notification display devices 201 to 204, it is provided at the lower right position on the first to fourth notification display devices 201 to 204. All of the circular light emitting areas that are present are turned off. For example, when the upper 4 digits of the total number data in the first calculation period is “1230”, “1230” is displayed on the first to fourth notification display devices 201 to 204. On the other hand, when the total number information in the second calculation period is displayed on the first to fourth notification display devices 201 to 204, it is provided at the lower right position on the first to fourth notification display devices 201 to 204. All of the circular light emitting areas are turned on. For example, when the upper 4 digits of the total number data of the second calculation period is “1230”, “1.2.3.0.” is displayed on the first to fourth notification display devices 201 to 204. It Thereby, the total number information of the first calculation period and the total number information of the second calculation period displayed on the first to fourth notification display devices 201 to 204 can be easily identified.

(107) In the 93rd to 97th embodiments, the normal entrance management process (step SM204 of the check process (FIG. 341)) is executed in the first timer interrupt process (FIG. 338), and the residual process is executed. The configuration is not limited to the configuration in which the total division execution process (FIG. 348) is executed in (FIG. 347), and the total division execution process (FIG. 348) is executed in the first timer interrupt process (FIG. 338). In addition to the above, a normal entrance management process (step SM204 of the check process (FIG. 341)) may be executed in the remaining process (FIG. 347). In the present configuration, in the residual process, the normal ball entry management process is executed to enter the ball entry parts 24a, 31 to 34 in a situation that is neither the open/close execution mode due to the jackpot result nor the high frequency support mode. The ball history is stored in the various counters 231a to 231e in the normal counter area 231. The work area 221 for specific control is provided with a stored flag. The stored flag is a flag that enables the main CPU 63 to know that the normal entrance management process has already been executed after the end of the first timer interrupt process. The stored flag is set to "1" when the normal entrance management process is executed in the remaining process. The stored flag is cleared to "0" when the first timer interrupt process is executed. In the remaining process, a normal entrance management process is executed on condition that "1" is not set in the stored flag. Therefore, even if the residual process is executed a plurality of times between the end of the first timer interrupt process and the start of the next first timer interrupt process, the opening/closing execution mode and the high-frequency support mode depending on the jackpot result will be executed. The number of times of occurrence of a ball entering each of the ball entrance portions 24a, 31 to 34 in a situation that is neither case is counted twice. The residual process is executed at least once between the end of the first timer interrupt process and the start of the next first timer interrupt process. In this configuration, in the first timer interrupt process, the calculation of the base value is performed by executing the aggregate division execution process (FIG. 348), and the latest base value calculated by the calculation overwrites the current area 311. To be done.

As described above, the total division execution process and the normal ball management process are set by being distributed to the first timer interrupt process and the residual process, so that the total division execution process and the normal ball management process are performed. Compared with the configuration in which both of the processes are set to the first timer interrupt process, the execution period of one process of the first timer interrupt process can be shortened. As a result, the remaining processing is performed once after the end of the first timer interrupt processing due to the extension of the execution period of the first timer interrupt processing until the start of the next first timer interrupt processing. It is possible to avoid the situation where it is not executed. In addition, in comparison with the configuration in which both the total division execution process and the normal entrance management process are set to the residual process, the generation of the first timer interrupt process and the second timer interrupt process occurs in step SM801 of the residual process. It is possible to shorten the period required after the prohibition until the generation of the first timer interrupt process and the second timer interrupt process is permitted in step SM807. As a result, the second timer interrupt process causes the second interrupt period (specifically, 2) due to the extension of the period in which the generation of the first timer interrupt process and the second timer interrupt process is prohibited in the residual process. It is possible to avoid a situation in which the first timer interrupt processing cannot be performed in the first interrupt cycle (specifically, 4 milliseconds), and a situation in which the first timer interrupt processing cannot be performed in a millisecond).

(108) In the 93rd to 97th embodiments, instead of the configuration in which the display indicating the degree of convergence of the base value (display of the total number information) is performed, the display indicating the degree of convergence of the payout rate. May be performed. The payout rate is the ratio of the total payout number to the total number of game balls discharged from the game area PA of the pachinko machine 10 in the entire game state. Further, the entire gaming state is a gaming state which is neither the open/close execution mode nor the high frequency support mode, the gaming state which is the open/close execution mode, and the gaming state which is the high frequency support mode. The work area 223 for non-specific control is provided with an incoming ball number counter area 596 (FIG. 322) as in the 89th embodiment. As described above with reference to FIG. 322 in the 89th embodiment, the general winning award counter 596a, the special electric prize award counter 596b, the first operation counter 596c, the second operation counter 596d, and An out counter 596e is provided. In various counters 596a to 596e in the incoming ball number counter area 596, the incoming ball numbers of the game balls in all the gaming states are measured without distinguishing the gaming states. The various counters 596a to 596e in the incoming ball number counter area 596 are for measuring the number of game balls entered in the targeted ball portions 24a and 31 to 34 in a situation where the front door frame 14 is in the closed state. Used for. Specifically, in the above-mentioned all game states, when one game ball enters the general winning opening 31, the value of the general prize counter 596a is incremented by 1, and one special game ball 32 in the special prize winning device 32. When the player enters, the value of the special electric prize winning counter 596b is incremented by 1, and when one game ball is entered into the first operating port 33, the value of the first operating counter 596c is incremented by 1, and the second When one game ball enters the operating port 34, the value of the second operation counter 596d is incremented by 1, and when one game ball enters the out port 24a, the value of the out counter 596e is increased. 1 is added.

Every time the total number of game balls discharged from the game area PA of the pachinko machine 10 in the entire gaming state reaches the shift reference number of 60,000, one calculation period for the payout rate ends and the next calculation is performed. The period begins. The values of the various counters 596a to 596e in the incoming ball number counter area 596 are set when the total number of gaming balls discharged from the gaming area PA of the pachinko machine 10 in the entire gaming state reaches the shift reference number of 60,000. 0” is cleared. When the values of the various counters 596a to 596e in the incoming ball number counter area 596 are K101 to K105, the payout rate is as follows.
-Dot rate: total payout number of game balls (K101 x "number of prize balls for winning in general prize hole 31" + K102 x "number of prize balls for winning in special electric prize winning device 32" + K103 x "first operating port 33" Ratio of the number of prize balls for winning the prize”+K104דthe number of prize balls for winning the second actuating port 34”)/the total number of game balls discharged from the game area PA (K101+K102+K103+K104+K105).

In the work area 223 for non-specific control, instead of the current area 311, the first history area 312, the second history area 313, and the third history area 314 in the 93rd embodiment, the latest payout rate is stored. The current payout rate area, the first payout rate history area in which the final payout rate in the previous calculation period is stored, and the final payout rate in the second previous calculation period are stored. A second payout rate history area and a third payout rate history area for storing the final payout rate in the calculation period three times before are provided. In the 1st to 4th display devices 201 to 204, every time the display continuation period (specifically, 5 seconds) elapses, the current state of the payout rate → the first payout rate history area → the second payout rate The payout rate to be notified is switched in a predetermined order of the history area→the third payout rate history area, and the switching of the payout rate to be notified is repeated in the predetermined order.

In the work area 223 for non-specific control, instead of the total number area 631 and the total payout number area 632 in the 93rd embodiment, a payout rate total number area and a payout rate total payout number area are provided. Has been. The payout rate total number area is a counter for storing the payout rate total number data, which is numerical information indicating the total number of game balls discharged from the game area PA in the entire gaming state. The main CPU 63 calculates the total payout rate number data by summing the values of the various counters 596a to 596e in the incoming ball number counter area 596. The total number data for the payout rate is 2-byte numerical information indicating any numerical value of “0” to “65535”.

The payout rate total payout quantity area is a counter for storing payout rate total payout quantity information, which is numerical information indicating the total payout quantity of game balls in all gaming states. The main CPU 63 calculates payout rate total payout amount information based on the values of various counters 596a to 596e in the incoming-ball number counter area 596. The total payout amount area for the payout rate is made up of 3 bytes and can store numerical information having a value obtained by subtracting 1 from the cube of “256” as an upper limit. When the values of the general prize counter 596a, the special electric prize counter 596b, the first operation counter 596c, and the second operation counter 596d in the number-of-balls counter area 596 are K101 to K104, the open/close execution mode and the high-frequency support mode depending on the jackpot result are displayed. The total payout number of game balls in a situation that is neither is calculated by the following formula.
-Total payout number: K101 x "number of prize balls for winning in the general prize hole 31" + K102 x "number of prize balls for winning in the special electric prize winning device 32" + K103 x "number of prize balls for winning in the first working port 33" +K104דthe number of prize balls for winning in the second operating port 34”.

The main side CPU 63 grasps the total payout number of the game balls in all the gaming states by grasping the total payout number information for the payout rate stored in the total payout number area for the payout rate, and also for the payout rate. By grasping the payout rate total number data stored in the total number area, the total number of game balls discharged from the game area PA in all the game states is grasped. Then, the payout rate is calculated as a numerical value up to the fourth decimal place by dividing the obtained total payout rate for payout rate by the grasped total number for payout rate. After that, the calculated payout rate is rounded off to the fourth decimal place to obtain a payout rate up to the third decimal place. After that, the payout rate is rounded to the second decimal place by rounding off the number at the third decimal place in the payout rate up to the third decimal place. Then, the most recent payout rate stored in the payout rate current area is updated by overwriting the payout rate up to the second decimal place in the payout rate current area.

In this configuration, when the reset button 68c (FIG. 53) is pressed while the most recent payout rate is being displayed on the first to fourth notification display devices 201 to 204, the first -The 4th notification display devices 201-204 display the total number information for payout rates in which the upper four digits of the total number data for payout rates are displayed. By making it possible to grasp the total number data for the payout rate in the current calculation period of the payout rate, the degree of convergence about the latest payout rate displayed on the first to fourth notification display devices 201 to 204. Can be grasped. When the total number information for payout ratios is displayed on the first to fourth notification display devices 201 to 204, the first notification display device 201 shows a digit of tens of thousands in the total number data for payout ratios. Is displayed on the second notification display device 202, and the thousands digit is displayed on the total payout rate total number data, and the third notification display device 203 is displayed on the three hundredth digit on the total payout rate total number data. Is displayed, and the tens digit of the total number data for payout rate is displayed on the fourth notification display device 204. As a result, it is possible to grasp the upper four digits of the total number data for payout rate, and also to grasp the degree of convergence of the latest payout rate.

The manager of the game hall is grasped based on the total number information for payout rate (upper 4 digits of the total number data for payout rate) displayed on the first to fourth notification display devices 201 to 204. If the total number data for payout rate is smaller than the total number data for payout rate (specifically, 60000) during the calculation period of the payout rate, the It can be understood that the degree of convergence is low. In addition, when the total coin number data for payout rate grasped based on the total number information is close to the final total coin count data for payout rate (specifically, 60000 pieces) in the calculation period of the coin payout rate, It can be understood that the degree of convergence of the latest payout rate is high. If the latest payout rate is out of the theoretical range of the payout rate, if the degree of convergence of the latest payout rate is low, the manager of the game hall will be the final player in the current calculation period. It is possible to understand that a high payout rate may fall within the theoretical value range of the payout rate. In addition, if there is a high degree of convergence of the latest payout rate, it is possible to understand that the final payout rate during the current calculation period is likely to fall outside the theoretical range of the payout rate. it can. A game hall that monitors the payout rate by the configuration in which the display of the payout rate and the display of the total number information for the payout rate are performed by the common first to fourth display devices 201 to 204. It is possible to reduce the monitoring burden on the administrator.

(109) In the 93rd, 95th, and 96th embodiments, when a process corresponding to non-specific control (test firing test execution process, management execution process, and total division execution process) is executed by the CALLI command, pop A configuration may be such that a program of a subroutine that executes an instruction, a DI instruction, and a call instruction (CALL instruction) is read. In the program of the subroutine, first, the instruction of “PUSH PSW” is executed, and the processing of saving the information of the flag register of the main CPU 63 to the stack area 222 for specific control is performed by the push instruction. By saving the information in the flag register before the program of the process corresponding to the non-specific control is started, it is changed after the call of the process corresponding to the non-specific control or the start of the process corresponding to the non-specific control. It is possible to save the information of the flag register in the state before the operation to the stack area 222 for specific control. After that, the DI instruction performs a process of inhibiting the interrupt of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346). As a result, during execution of the process corresponding to the non-specific control, the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346), which are processes corresponding to the specific control, are not interrupted and activated. It becomes possible to do so. After that, the processing corresponding to the non-specific control is executed by the call instruction (CALL instruction). As described above, even when the program of the subroutine for executing the pop instruction, the DI instruction, and the call instruction (CALL instruction) is read when the process corresponding to the non-specific control is executed by the CALLI instruction, the main CPU 63 A process corresponding to the non-specific control in a state where the information of the flag register is saved in the stack area 222 for specific control and the interrupts of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346) are prohibited. Can start. As already described in the 93rd Embodiment, in the first timer interrupt process (FIG. 338) and the residual process (FIG. 347), the CALLI instruction executes a total of three processes corresponding to the non-specific control. ..

Therefore, a program for executing a pop instruction, a DI instruction, and a call instruction (CALL instruction) is stored in the main side ROM 64 as a subroutine program read when a process corresponding to the non-specific control is executed by the CALLI instruction. Therefore, even if the program is read and executed when the processes corresponding to the above three non-specific controls are executed by the CALLI instruction, the first timer interrupt process (FIG. 338) and the residual process (FIG. 347). ) Can reduce the data capacity of the program for executing. As a result, the storage capacity in the main ROM 64 for storing the program for executing the first timer interrupt process (FIG. 338) and the residual process (FIG. 347) can be reduced.

(110) In the 93rd embodiment, instead of the configuration in which the management execution process (FIG. 340) is executed in step SL821 of the first timer interrupt process (FIG. 338), the management execution process is the residual process (FIG. 347). Thus, the management execution process is configured to be executed in the residual process (FIG. 347), whereby the execution period of the first timer interrupt process (FIG. 338) can be shortened. Specifically, in step SM806 of the residual processing (FIG. 347), the management execution processing and the total division execution processing are executed by the CALLI command. When the management execution process and the total division execution process are executed by the CALLI instruction, the information in the flag register of the main CPU 63 is first saved in the stack area 222 for specific control. By saving the information of the flag register before the program of the process (management execution process and total division execution process) corresponding to the non-specific control is started, the call of the process corresponding to the non-specific control or the non-specific control is performed. It is possible to save the information of the flag register in the state before change after the start of the process corresponding to the control in the stack area 222 for the specific control.

When the management execution process and the total division execution process are executed by the CALLI instruction, the first timer interrupt process (FIG. 338) and the second timer are performed after the flag register information is saved in the stack area 222 for specific control. Interrupt processing (FIG. 346) interrupts are prohibited. Therefore, the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 338) that are processes corresponding to the specific control are performed while the management execution process and the total division execution process that are processes corresponding to the non-specific control are being executed. 346) is not interrupted and activated.

When the management execution process and the total division execution process are executed by the CALLI instruction, the information in the flag register is saved in the stack area 222 for specific control, and the first timer interrupt process (FIG. 338) and the second timer interrupt process are performed. After the interrupt of FIG. 346 is prohibited, the program corresponding to the management execution process is started. Further, after the management execution processing is completed, the program corresponding to the total division execution processing is started.

In this way, by adopting the configuration in which the management execution process and the total division execution process are executed by the CALLI instruction, the information of the flag register of the main CPU 63 is transferred to the stack area 222 for specific control by one instruction (“CALLI”). Can be programmed to correspond to the management execution process by disabling the interrupts of the first timer interrupt process (FIG. 338) and the second timer interrupt process (FIG. 346), and after the management execution process ends. , A program corresponding to the total division execution processing can be started. Therefore, the instruction for saving the information in the flag register of the main CPU 63 to the stack area 222 for specific control and the interruption of the first timer interrupt processing (FIG. 338) and the second timer interrupt processing (FIG. 346) are prohibited. Management execution processing and aggregation division execution processing, as compared with a case in which an instruction to start the management execution processing program, an instruction to start the management execution processing program, and an instruction to start the aggregation division execution processing program are provided separately. It is possible to reduce the number of instructions set in the program corresponding to the residual processing (FIG. 347) for executing the. As a result, the storage capacity of the main ROM 64 for storing the program corresponding to the residual processing (FIG. 347) can be reduced.

In the management execution process of this configuration, the processes of steps SM101 to SM108 of the management execution process (FIG. 340) in the 93rd embodiment are executed, while the processes of steps SM109 to SM116 are not executed and tabulated. The program corresponding to the division execution process is started. Further, in the aggregation/division execution process in this configuration, the processes of steps SM908 to SM907 are executed without executing the processes of steps SM901 to SM907 of the aggregation/division execution process (FIG. 348) in the 93rd embodiment. To be done. Since the management execution process and the total division execution process, which are processes corresponding to the non-specific control, are continuously executed, the WA register, the BC register, the DE register, and the HL register of the main CPU 63 in the management execution process. , IX register and IY register information to restore the information corresponding to the specific control immediately before the processing corresponding to the non-specific control is started (step SM109 to step SM115) and to execute the RETI instruction The process (step SM116) can be omitted. As a result, the storage capacity of the main ROM 64 for storing the program corresponding to the management execution process can be reduced. In addition, in the total division execution process, a process of setting Y(u+2), which is information of the last address in the non-specific control stack area 224, as a fixed address at the start of the non-specific control in the stack pointer of the main CPU 63 ( Step SM901) and processing for saving each information of the WA register, BC register, DE register, HL register, IX register, and IY register of the main CPU 63 to the corresponding buffer in the work area 223 for non-specific control (step SM902 to step SM907) can be omitted. As a result, the storage capacity of the main ROM 64 for storing the program corresponding to the total division execution processing can be reduced.

(111) In the 94th and 95th embodiments, the error detection process for detecting the latest abnormality of the base value is executed as the process corresponding to the non-specific control, and the error detection process is the first. A configuration may be employed in which the test firing test execution process and the management execution process in the timer interrupt process (FIG. 350 in the 94th embodiment and FIG. 353 in the 94th embodiment) are performed continuously. As already described in the 94th and 95th embodiments, the test shot test execution process and the management execution process are processes corresponding to non-specific control. In the 94th embodiment, after the test firing test execution processing is executed by the call instruction (CALL instruction) in step SN221 of the first timer interrupt processing (FIG. 350), the error detection processing is executed by the call instruction (CALL instruction). To do. After that, the management execution processing is executed by the call instruction (CALL instruction). With the configuration in which the test shot test execution process, the error detection process, and the management execution process corresponding to the non-specific control are continuously performed, the process corresponding to the specific control in the first timer interrupt process (FIG. 350) is changed from the non-specific control to the non-specific control. Increase the processing content of the processing corresponding to non-specific control while avoiding an increase in the number of times of switching to processing corresponding to, and return from processing corresponding to non-specific control to processing corresponding to specific control Can be made In the 95th embodiment, the non-specific control is performed in the order of the test shot test execution process→the error detection process→the management execution process by the CALLI command in step SN519 of the first timer interrupt process (FIG. 353). One process is executed continuously. As a result, the number of times of switching from the process corresponding to the specific control to the process corresponding to the non-specific control and the return from the process corresponding to the non-specific control to the process corresponding to the specific control in the first timer interrupt process (FIG. 353). It is possible to increase the processing content of the processing corresponding to the non-specific control while avoiding an increase in

In the error detection process, first, the error detection table stored in advance as data for non-specific control is read from the main ROM 64. Numerical information of the upper limit of the theoretical value range of the base value and numerical information of the lower limit of the theoretical value range of the base value are set in the error detection table. After that, it is determined whether the latest base value stored in the current area 311 is within the theoretical value range of the base value. Then, when it is determined that the latest base value is not within the theoretical value range of the base value, "1" is set to the base value error flag provided in the work area 223 for non-specific control, and the latest base value is set. When it is determined that the base value is within the theoretical value range of the base value, the base value error flag is cleared to "0". The base value error flag is a flag that enables the main CPU 63 to grasp whether the latest base value stored in the current area 311 is within the theoretical value range of the base value.

In this configuration, the external information setting process (step SN218 in the 94th embodiment, step SN218 in the 94th embodiment) of the first timer interrupt process (FIG. 350 in the 94th embodiment, FIG. 353 in the 95th embodiment) is performed. In SN518), it is determined whether or not the base value error flag in the work area 223 for non-specific control is set to "1" at a predetermined time interval (for example, every 30 minutes), and the base value error flag is set to "1". If "" is set, the base value error is notified. In the base value error notification, a base value error signal is externally output to an external device such as a hall computer. When the manager of the game hall confirms the base value error signal with an external device such as a hall computer, the latest base value stored in the current area 311 is displayed on the first to fourth notification display devices 201 to 204. By pressing the reset button 68c in the displayed state, it is possible to display the upper 4 digits of the total number data on the first to fourth notification display devices 201 to 204, and also to display the latest base value. The degree of convergence of can be grasped.

(112) In the 96th embodiment, the display unit for displaying the total number of pieces is the special figure display unit 641a and the general figure when the setting value is being updated and the setting value is being confirmed. The display unit 642a is not limited to the display unit 642a, and the total number display may be performed on the first special figure display unit and the second special figure display unit. Specifically, in the 65th to 71st embodiments, eight LEDs are arranged in a horizontal row instead of the first special figure display unit 425 and the second special figure display unit 426 (FIG. 209(b)). The first special figure display part and the second special figure display part are provided. The first special figure display part and the second special figure display part are areas in which the game ball does not pass in the game area PA, like the special figure display part 641a and the general figure display part 642a in the 96th embodiment. It is provided in the lower right corner. The eight LEDs in the second special figure display unit are provided below the eight LEDs in the first special figure display unit.

The work area 223 for non-specific control is provided with the normal counter area 231 and the total number area 631 (FIG. 336(a)) in the 93rd embodiment. As already described in the 93rd embodiment, the total number area 631 is a game ball discharged from the game area PA in a situation where neither the open/close execution mode by the big hit result nor the high frequency support mode is present in the current calculation period. Is a counter that stores the total number data, which is numerical information indicating the total number (that is, the total number of game balls supplied to the game area PA). The main CPU 63 calculates the total number data in the current calculation period by adding the values of the various counters 231a to 231e in the normal counter area 231. The total number data is 2-byte numerical value information indicating a numerical value of "0" to "65535".

The eight LEDs in the first special figure display portion have a one-to-one correspondence with the lower eight bits (0th to 7th bits) of the total number data. Specifically, the nth LED (n is an integer from 1 to 8) from the right in the first special figure display unit corresponds to the (n-1)th bit in the total number data. Further, the eight LEDs in the second special figure display portion have a one-to-one correspondence with the upper 8 bits (8th to 15th bits) of the total number data. Specifically, the m-th LED (m is an integer from 1 to 8) from the right in the second special figure display portion corresponds to the (m+7)th bit in the total number data. In the total number display, when the value of the bit corresponding to the LED is “1”, the LED is turned on, and when the value of the bit corresponding to the LED is “0”, the LED is turned off. Thus, the light emission control of each LED in the first special figure display portion and the second special figure display portion is performed.

Similar to the 65th embodiment, the clear target area 371 (FIG. 223) in the specific control work area 221 stores display data for causing the first special figure display unit to perform a predetermined display. A first display data buffer 271 (FIG. 223) and a sixth display data buffer 471 (FIG. 223) that stores display data for causing the second special figure display unit to perform a predetermined display are provided. When the setting value is being updated or the setting value is being confirmed, the main CPU 63 displays the lower 8 bits of the total number data stored in the total number area 631 as display data. Is set in the first display data buffer 271 (FIG. 223) and the upper 8 bits of the total number data are set as display data in the sixth display data buffer 471 (FIG. 223). Accordingly, the display control of the eight LEDs in the first special figure display unit is performed in a manner corresponding to the lower 8 bits of the total number data, and the second special figure is performed in a manner corresponding to the upper 8 bits of the total number data. Display control of eight LEDs in the display unit is performed.

As a result, in the situation where the setting value is being updated, a display indicating that the setting value is being updated and a display indicating the current setting value are performed. It is possible to display the total number of pieces of data indicating the total number of pieces of data by using the first special figure display portion and the second special figure display portion, which are display portions different from the display units 204 to 204. Therefore, the manager of the game hall can grasp the information of the total number data even when the setting value is being updated, and also grasp the degree of convergence of the latest base value. be able to. In addition, in a situation where the setting value is being confirmed, a display indicating that the setting value is being confirmed and a display indicating the current setting value are performed. Using the first special figure display section and the second special figure display section, which are display sections different from 204, the total number display showing the total number data can be performed. Therefore, the manager of the game hall can grasp the information of the total number data even when the setting value is being confirmed, and also grasp the degree of convergence of the latest base value. be able to.

(113) In the 96th embodiment, in the situation where the setting value is being updated and the setting value is being confirmed, the eight LEDs of the special figure display portion 641a and the general figure display portion are displayed. While the total number display showing the total number data is performed using the eight LEDs 642a, the total number information (upper 4 digits of the total number data) is displayed on the first to fourth notification display devices 201 to 204. The display may not be performed. As a result, the total number display performed on the special figure display unit 641a and the general figure display unit 642a while eliminating the configuration for displaying the total number information on the first to fourth notification display devices 201 to 204. It is possible to grasp the total number data based on the above, and also to grasp the degree of convergence of the latest base value.

Further, in the configuration of (113) above, the reset button 68c is pressed in a situation where the most recent base value stored in the current area 311 is being displayed on the first to fourth notification display devices 201 to 204. The total number may be displayed on the special figure display unit 641a and the general figure display unit 642a for a predetermined period (specifically, 5 seconds) based on the operation being performed. As a result, the latest base value is displayed on the first to fourth notification display devices 201 to 204, and the total number display is performed on the special figure display unit 641a and the general figure display unit 642a. Can be produced. This makes it possible to simultaneously grasp the latest base value and the degree of convergence of the latest base value.

(114) In each of the above-described embodiments, the display device on which the information of the base value is displayed needs to be supplied with operating power when rewriting the display content, such as electronic paper, and the operating power is needed when storing and retaining the display content. A display device that does not need to be supplied may be used. Thereby, even when the supply of operating power to the pachinko machine 10 is stopped, it becomes possible to grasp the information of the base value by visually recognizing the display device.

(115) Instead of the configuration in which the display control device 82 is controlled by the audio emission control device 81 based on the command transmitted from the main control device 60, the display control is performed based on the command transmitted from the main control device 60. The device 82 may control the audio emission control device 81. Further, instead of the configuration in which the sound emission control device 81 and the display control device 82 are separately provided, both control devices may be provided as one control device, and the function of one of the both control devices may be provided. May be integrated in the main control device 60, and both functions of the both control devices may be integrated in the main control device 60. Further, the configuration of the command transmitted from the main control device 60 to the sound emission control device 81 and the configuration of the command transmitted from the sound emission control device 81 to the display control device 82 are also arbitrary.

(116) Other types of pachinko machines different from the above embodiments, such as a pachinko machine in which an electric accessory opens a predetermined number of times when a game ball enters a specific area of a special device, or a game ball in a specific area of a special device. The present invention is also applicable to gaming machines such as pachinko machines in which a right is generated and a big hit is generated, pachinko machines equipped with other accessories, arrange ball machines, and sparrow balls.

Further, a non-ball-ball type gaming machine, for example, provided with a plurality of reels provided with a plurality of types of symbols in the circumferential direction, the rotation of the reel is started by inserting a medal and operating the start lever, and the stop switch is operated. After the reels stop after a predetermined time has elapsed, if a specific symbol or a combination of specific symbols is established on the effective line visible from the display window, a bonus such as payout of medals is given to the player. The present invention can be applied to a slot machine.

In addition, the game machine main body that is openably and closably supported by the outer frame is provided with a storage unit and a loading device, and the start lever is operated after a predetermined number of game balls stored in the storage unit are loaded by the loading device. The present invention can also be applied to a gaming machine in which a pachinko machine and a slot machine are integrated, in which the reel starts to rotate.

When the present invention is applied to a slot machine or a gaming machine in which a pachinko machine and a slot machine are fused, for example, the result of the lottery process of the winning combination executed when one game is started based on the operation of the start lever is history information. It may be configured such that the actual winning probability of each winning combination is calculated using the history information, and when a transition to a special game state such as a bonus game occurs, it is stored as history information and the history thereof is stored. The information may be used to calculate the actual transition probability to the special game state, or the ratio of the number of stay games in the special game state to the total number of exhausted games may be calculated. The history information and various parameters may be read by an external device, or the gaming machine itself may be informed of the result of calculation of various parameters. Further, it may be configured such that there are a plurality of stages of setting states such as “setting 1” to “setting 6”, and the winning probability in the lottery process of the winning combination is changed according to the setting state. In this case, the configuration in each of the above embodiments may be applied to the handling of history information when the setting of the setting state is newly set or the setting value is changed, the calculation of various parameters, and the handling of repeated changes. ..

(117) The characteristic configurations of the first to 97th embodiments may be mutually applied in any combination. For example, the characteristic configuration of the first embodiment, the characteristic configuration of the sixth embodiment, the characteristic configuration of the tenth embodiment, and the characteristic configuration of the thirtieth embodiment. Configuration, characteristic configuration of the 45th embodiment, characteristic configuration of the 55th embodiment, characteristic configuration of the 64th embodiment, characteristic of the 75th embodiment The above configurations may be combined, and the characteristic configuration of the second embodiment, the characteristic configuration of the fourth embodiment, the characteristic configuration of the eighth embodiment, and Characteristic configuration of the eleventh embodiment, characteristic configuration of the 33rd embodiment, characteristic configuration of the 43rd embodiment, and characteristic configuration of the 58th embodiment. The characteristic configuration of the 65th embodiment may be combined with the characteristic configuration of the 74th embodiment, and the characteristic configuration of the first embodiment and the 15th embodiment may be combined. Characteristic configuration of the embodiment, characteristic configuration of the 21st embodiment, characteristic configuration of the 29th embodiment, characteristic configuration of the 34th embodiment, the 49, a characteristic configuration of the 60th embodiment, a characteristic configuration of the 69th embodiment, and a characteristic configuration of the 72nd embodiment, May be combined, and the characteristic configuration of the second embodiment, the characteristic configuration of the sixteenth embodiment, the characteristic configuration of the twenty-second embodiment, and the thirty-fifth implementation. Characteristic configuration of the embodiment, characteristic configuration of the 39th embodiment, characteristic configuration of the 53rd embodiment, characteristic configuration of the 62nd embodiment, the 71st The characteristic configuration of the above embodiment, the characteristic configuration of the above 73rd embodiment, the characteristic configuration of the above 76th embodiment, and the characteristic configuration of the above 97th embodiment. You may combine. Further, in addition to the configuration in which the characteristic configurations of the above-described first to 97th embodiments are applied in a predetermined combination, the configuration in the above-described another mode may be applied in any combination.

<Regarding invention groups extracted from the above embodiments>
The features of the invention group extracted from each of the above-described embodiments will be described below, showing effects and the like as necessary. It should be noted that, in the following, for ease of understanding, the configurations corresponding to the above-described embodiments are appropriately shown in parentheses or the like, but the present invention is not limited to the specific configurations shown in brackets or the like.

<Feature A group>
Features A1. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (a function for executing the setting value updating process in the main CPU 63),
When a predetermined event occurs due to execution of a game, history storage execution means (a function of executing history setting processing in the management-side CPU 112) for storing history information of a game corresponding to the predetermined event in the history storage means (history memory 117) )When,
An information erasing unit that erases at least a part of the history information stored in the history storage unit under at least one condition that the setting value to be used is set by the setting unit (third part). In the fifth embodiment, the function of executing the process of step S1809 in the management-side CPU 112, the function of executing the process of step S2109 in the management-side CPU 112 in the fifth embodiment, and the function of performing the process of step S2109 in the sixth embodiment. A function of executing the process of S2308, a function of executing the process of step S2608 in the management CPU 112 in the eighth embodiment),
A gaming machine characterized by being equipped with.

According to the characteristic A1, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player can use the more advantageous setting value as the usage target. Will be expected. When a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage means. As a result, it becomes possible to store and hold information for managing the number of occurrences or the frequency of occurrence of a predetermined event in the gaming machine, and it is preferable to manage the frequency of occurrence of the predetermined event by using this managed information. It becomes possible to do it. Further, since the history information is stored in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification.

In this case, at least a part of the history information stored in the history storage means is deleted under the condition that at least one of the setting values to be used is newly set. This makes it possible to adjust the content of the history storage means so that the frequency of occurrence of the predetermined event in the situation after the new setting of the setting value to be used is performed can be suitably performed. ..

Feature A2. Ball entry means (first operation port 33, second operation port 34) into which a game ball flowing down the game area can enter,
Information acquisition means (function for executing the process of step S401 in the main CPU 63) for acquiring special information based on the fact that a game ball has entered the ball entrance means,
An assignment determination unit that determines whether or not the special information corresponds to the assignment information (a function of the main CPU 63 that executes the processes of steps S503 and S504);
A privilege granting means (a step in the main CPU 63) for granting a privilege (opening/closing execution mode) to the player based on the result of the grant corresponding that the special information corresponds to the grant information in the grant determination. The function of executing the processing of S409 to step S412),
The gaming machine according to Feature A1, wherein the probability of being the grant correspondence result in the grant determination varies according to the set value.

According to the feature A2, it is possible to change the probability of the assignment correspondence result in the so-called pachinko machine according to the set value. In this case, since the configuration of the characteristic A1 is provided, it is possible to appropriately manage the occurrence frequency of the predetermined event in the situation after the probability of the assignment correspondence result is changed. It is possible to adjust the content.

Features A3. The information erasing means erases all the history information stored in the history storage means under at least one condition that the setting value to be used is set by the setting means. The game machine according to A1 or A2.

According to the characteristic A3, all the history information stored in the history storage means is erased when the setting value to be used is newly set, and thus the setting value to be used is set. It becomes possible to specify the frequency of occurrence of the predetermined event with reference to the timing of the new occurrence.

Features A4. The information erasing means erases a part of the history information stored in the history storage means under at least one condition that the setting value to be used is set by the setting means, The gaming machine according to feature A1 or A2, characterized in that a part of the history information stored in the history storage means is left.

According to the characteristic A4, when the setting value to be used is newly set, the history information unnecessary for the management of the frequency of occurrence of the predetermined event thereafter is deleted, and the management of the frequency of occurrence of the predetermined event thereafter is performed. It becomes possible to leave necessary history information. As a result, it becomes possible to preferably manage the occurrence frequency of the predetermined event after the setting of the setting value to be used is newly set.

Features A5. The history information stored in the history storage means includes first history information (a history indicating that an open/close execution mode has occurred) in which the probability of occurrence of the predetermined event corresponding to the history information varies according to the set value. Information) and second history information (history information indicating that a game ball has been discharged from the game area PA) that does not change according to the set value.
The information erasing means erases the first history information stored in the history storing means, under at least one condition that the setting value to be used is set by the setting means, The gaming machine according to feature A4, characterized in that the second history information stored in the history storage means is left.

According to characteristic A5, when the setting value to be used is newly set, the first history information corresponding to the predetermined event in which the occurrence probability changes according to the setting value is erased, and the occurrence probability is set to the set value. The second history information corresponding to the predetermined event that does not change according to is not deleted. As a result, when the first history information before the setting of the setting value to be used is newly performed is succeeded after the setting of the setting value is newly performed, a predetermined event corresponding to the first history information is generated. The first history information, which is not preferable in specifying the frequency, can be deleted when the setting of the setting value is newly performed. On the other hand, the second history information is referred to when the frequency of occurrence of the predetermined event corresponding to the second history information is specified by not deleting even if the setting value to be used is newly set. Since it is possible to secure a large number of second history information, it is possible to accurately specify the occurrence frequency of the predetermined event corresponding to the second history information.

Features A6. Ball entry means (first operation port 33, second operation port 34) into which a game ball flowing down the game area can enter,
Information acquisition means (function for executing the process of step S401 in the main CPU 63) for acquiring special information based on the fact that a game ball has entered the ball entrance means,
An assignment determination unit that determines whether or not the special information corresponds to the assignment information (a function of the main CPU 63 that executes the processes of steps S503 and S504);
A privilege granting means (a step in the main CPU 63) for granting a privilege (opening/closing execution mode) to the player based on the result of the grant corresponding that the special information corresponds to the grant information in the grant determination. The function of executing the processing of S409 to step S412),
It is a configuration in which the probability of being the assignment correspondence result in the assignment determination varies according to the setting value,
The first history information includes information corresponding to the grant of the privilege,
The game machine according to feature A5, wherein the second history information includes information corresponding to the discharge of the game balls from the game area in a predetermined manner.

According to the characteristic A6, since the award probability of the privilege varies depending on the set value, the first history information should be deleted when the setting of the set value to be used is newly set. Thus, it is possible to specify the privilege grant frequency under the condition of the newly set setting value. On the other hand, since the frequency with which the game balls are discharged from the game area does not change according to the set value, the second history information is not deleted even if a new set value to be used is set. It is possible to accurately specify the frequency with which the game balls are discharged from the game area in a predetermined manner.

Features A7. The information erasing means, when the setting value to be used is set by the setting means, when at least a predetermined amount of the history information is stored in the history storage means, at least the history information is stored. The gaming machine according to any one of features A1 to A6, which is characterized by erasing a part.

According to the feature A7, when the predetermined history information is not stored in the history storage unit in the predetermined amount or more, the history information is not deleted even if a new setting value to be used is set. This makes it possible to prevent the history information stored in the history storage means from being repeatedly erased even if a new setting of the set value is repeated in a situation where no game is played.

Feature A8. Corresponding to the result of the game in a predetermined period by using the history information stored in the history storage means, with at least one condition that the setting value to be used by the setting means is set. Information deriving means for deriving the mode information (the function of executing the process of step S1807 in the management CPU 112 in the third embodiment, the function of executing the process of step S2107 in the management CPU 112 in the fifth embodiment). The gaming machine according to any one of the features A1 to A7.

According to the characteristic A8, at least a part of the history information stored in the history storage means is provided with the configuration of the characteristic A1 and at least one condition that a new setting value to be used is set. In the configuration to be erased, a mode corresponding to the result of the game in a predetermined period by using the history information stored in the history storage means triggered by the new setting of the setting value to be used Information is derived. As a result, even if at least a part of the history information is deleted when the setting value is changed, the management result of the game history such as the frequency of occurrence of a predetermined event in the situation before the setting value is changed is grasped. It becomes possible to do.

Feature A9. The gaming machine according to Feature A8, further comprising a mode information storage unit (separate storage memory 171) that stores the mode information derived by the information derivation unit.

According to the characteristic A9, the mode information corresponding to the result of the game in a predetermined period by using the history information stored in the history storage means triggered by the new setting of the setting value to be used. Is derived, the mode information is stored in the mode information storage means. As a result, even if the set value is changed, it is possible to grasp the management result of the game history in the situation before the set value is changed at an arbitrary timing thereafter.

Feature A10. The amusement machine according to feature A9, wherein the aspect information storage means can store a plurality of the aspect information.

According to the characteristic A10, since it is possible to store a plurality of mode information in the mode information storage means, the management result of the game history in a plurality of periods is grasped on the basis of the timing when the new setting of the setting value is performed. It becomes possible to do. Further, even if new setting of the set value is repeated under the situation where the game is not played, the aspect information derived by utilizing the history information of the situation where the game is substantially played is the aspect information storage means. It is possible to increase the possibility of remaining in.

Feature A11. The aspect information storage means can store a predetermined number of the aspect information,
The gaming machine is a means for executing special processing when the setting value to be used by the setting means is set a predetermined number of times under a predetermined condition (in the third embodiment, in the management CPU 112). The gaming machine according to the feature A9 or A10, which is provided with a function of executing a monitoring process of repeated changes, and a function of performing a monitoring process of repeated changes in the main CPU 63 in the fourth embodiment.

According to the characteristic A11, the set value is set in a situation in which the game is not played so that the mode information derived by using the history information of the situation in which the game is substantially played does not remain in the mode information storage means. When the new setting of is repeated, special processing is executed for it. This makes it possible to deal with the act.

Feature A12. The game machine according to any one of features A8 to A11, wherein the information deriving unit derives the aspect information when the history storage unit stores a predetermined amount or more of the predetermined history information. ..

According to the characteristic A12, since the form information is derived when the predetermined amount of history information is stored in the history storage means in a predetermined amount or more, it is possible to prevent the form information from being unnecessarily derived. ..

Feature A13. The information erasing means erases the history information from when the setting value to be used is set by the setting means until a predetermined amount or more of the predetermined history information is stored in the history storage means. Without setting the set value to be used by the setting unit before the setting of the set value is performed when the history information is stored in the history storage unit in a predetermined amount or more. The gaming machine according to any one of features A1 to A12, characterized in that the history information stored in the history storage means is erased.

According to the characteristic A13, until a predetermined amount of predetermined history information is newly stored in the history storage means, even if a new setting value to be used is set, it is stored before the setting is performed. The history information that has been displayed is not deleted. As a result, even if a new setting value is set, it is possible to specify the management result of the game history in a predetermined period.

Feature A14. The history storage unit includes a first history storage unit (first history memory 191) and a second history storage unit (second history memory 192),
The history storage executing means,
When the predetermined event occurs in a predetermined period from when the setting value to be used is set by the setting unit to when a release condition is satisfied, the history information corresponding to the predetermined event is stored in the first history storage unit and Means for storing in both of the second history storage means (function for executing the processing of step S2604 in the management side CPU 112);
When the predetermined event occurs in a period other than the predetermined period, a unit that stores the corresponding history information in the side set as a storage target of the first history storage unit and the second history storage unit (Function of executing the process of step S2603 in the management CPU 112),
Equipped with
The information erasing means erases the history information stored in the side of the first history storage means and the second history storage means that has been set as the storage target until then, when the cancellation condition is satisfied. The gaming machine according to any one of features A1 to A13.

According to the characteristic A14, until a specific amount of history information is newly stored in the history storage unit, even if a new setting value to be used is set, it is stored before the setting is performed. The history information is not deleted. As a result, even if a new setting value is set, it is possible to specify the management result of the game history in a predetermined period. Further, the effect can be brought about only by appropriately changing the history storage means for storing history information between the first history storage means and the second history storage means.

Feature A15. Using the history information stored on the side set as the storage target of the first history storage unit and the second history storage unit, the mode information corresponding to the result of the game in a predetermined period is derived. The gaming machine according to Feature A14, which is provided with an information deriving unit (a function of the management-side CPU 112 that executes the process of step S2703).

According to the characteristic A15, even if the history information is stored in both the first history storage means and the second history storage means due to the new setting of the setting value, the aspect using the history information It is possible to appropriately derive the information.

In addition, with respect to the configurations of the features A1 to A15, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1-. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, Any one or a plurality of configurations of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature B group>
Feature B1. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (a function for executing the setting value updating process in the main CPU 63),
When a predetermined event occurs due to execution of a game, history storage execution means (a function of executing history setting processing in the management-side CPU 112) for storing history information of a game corresponding to the predetermined event in the history storage means (history memory 117) )When,
Equipped with
The predetermined history information stored in the history storage unit before the setting of the setting value to be used by the setting unit is performed by the setting unit to set the setting value to be used. A gaming machine characterized by being stored and held in the history storage means even after being played.

According to the characteristic B1, the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, so that the player can use the more advantageous setting value as the usage target. Will be expected. When a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage means. As a result, it becomes possible to store and hold information for managing the number of occurrences or the frequency of occurrence of a predetermined event in the gaming machine, and it is preferable to manage the frequency of occurrence of the predetermined event by using this managed information. It becomes possible to do it. Further, since the history information is stored in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification.

In this case, even if the setting value to be used is newly set, the history information stored in the history storage means is not erased but stored and retained. As a result, even if the setting value to be used is set, the history information up to that point can be continuously stored in the history storage means, and accumulated in the history storage means over a long period of time. It is possible to specify the management result of the game history by using the history information.

Feature B2. The history storage executing means stores the history information corresponding to the setting value to be used in the history storing means when the setting value is set by the setting means. In the embodiment, the management side CPU 112 has a function of executing the process of step S1307, and in the seventh embodiment the management side CPU 112 has a function of executing the process of step S2408). Machine.

According to the characteristic B2, even if the setting value to be used is newly set, the setting value to be used is newly set in the configuration in which the history information is not deleted and stored and retained. The history information corresponding to that is stored in the history storage means. As a result, it becomes possible to distinguish between the history information before the setting value to be used is newly set and the history information after the setting value is newly set.

Feature B3. When the setting value to be used is set by the setting unit, the storage execution unit at the time of setting stores information corresponding to the set value set in the history storage unit as the history information. The gaming machine according to feature B2.

According to the feature B3, it is possible to specify the content of the setting value set in the past by referring to the history information.

Feature B4. The history storage means includes a plurality of corresponding history storage means (history memories 181 to 186 for settings 1 to 6) corresponding to each of a plurality of types of setting values that can be set by the setting means. The gaming machine according to any one of the features B1 to B3.

According to the characteristic B4, since the correspondence history storage means is provided corresponding to each set value, it is possible to store the history information separately for each set value.

Feature B5. When the setting value to be used is set by the setting means, the correspondence history storage means corresponding to the set value is set as a target for storing the history information thereafter (management side) (A function of executing the process of step S2406 in the CPU 112) The gaming machine according to feature B4.

According to the feature B5, when the setting value to be used is newly set, the corresponding history storage unit corresponding to the setting value is set as the subsequent storage object of the history information. It is possible to distinguish and store the history information.

Feature B6. Information derivation means (display output processing in the management side CPU 112) for deriving mode information corresponding to the result of the game in a predetermined period using the history information stored in the correspondence history storage means that is the storage target. The game machine according to feature B5, which is provided with a function for executing.

According to the feature B6, in the configuration in which the history information is stored separately for each set value, it becomes possible to derive the mode information corresponding to the currently set set value.

Feature B7. Ball entry means (first operation port 33, second operation port 34) into which a game ball flowing down the game area can enter,
Information acquisition means (function for executing the process of step S401 in the main CPU 63) for acquiring special information based on the fact that a game ball has entered the ball entrance means,
An assignment determination unit that determines whether or not the special information corresponds to the assignment information (a function of the main CPU 63 that executes the processes of steps S503 and S504);
A privilege granting means (a step in the main CPU 63) for granting a privilege (opening/closing execution mode) to the player based on the result of the grant corresponding that the special information corresponds to the grant information in the grant determination. The function of executing the processing of S409 to step S412),
The gaming machine according to any one of features B1 to B6, wherein the probability of being the assignment correspondence result varies in the assignment determination according to the setting value.

According to the feature B7, it is possible to change the probability of the assignment correspondence result in the so-called pachinko machine according to the set value.

In addition, with respect to the configurations of the features B1 to B7, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1-. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic C group>
Feature C1. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (a function for executing the setting value updating process in the main CPU 63),
When a predetermined event occurs due to execution of a game, history storage execution means (a function of executing history setting processing in the management-side CPU 112) for storing history information of a game corresponding to the predetermined event in the history storage means (history memory 117) )When,
After setting the setting value to be used by the setting means, the history information is not erased until at least a predetermined amount of the history information is stored in the history storage means. (A function of executing the processing of steps S2506 and S2605 to S2609 in the management-side CPU 112),
A gaming machine characterized by being equipped with.

According to the characteristic C1, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player sets the more advantageous setting value as the usage target. Will be expected. When a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage means. As a result, it becomes possible to store and hold information for managing the number of occurrences or the frequency of occurrence of a predetermined event in the gaming machine, and it is preferable to manage the frequency of occurrence of the predetermined event by using this managed information. It becomes possible to do it. Further, since the history information is stored in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification.

In this case, until a specific amount of predetermined history information is newly stored in the history storage means, even if a new setting value to be used is set, it is stored before the setting. The history information is not deleted. As a result, even if a new setting value is set, it is possible to specify the management result of the game history in a predetermined period.

Feature C2. The post-setting correspondence means sets the set value when a predetermined amount or more of the predetermined history information is stored in the history storage means after the setting value to be used is set by the setting means. The gaming machine according to Feature C1, wherein the history information stored in the history storage unit is erased before being performed.

According to the characteristic C2, when the history storage means stores a specific amount of history information that enables the specification of the management result of the game history within a predetermined period after the new setting of the setting value is performed. Deletes the history information stored in the history storage unit before the new setting of the set value is performed. This makes it possible to prevent wasteful history information from being continuously stored in the history storage means.

Feature C3. The history storage unit includes a first history storage unit (first history memory 191) and a second history storage unit (second history memory 192),
The history storage executing means,
When the predetermined event occurs, a unit that stores the history information corresponding to the one of the first history storage unit and the second history storage unit that is set as a storage target (step S2603 in the management-side CPU 112). Function that executes the process of
After the setting value to be used is set by the setting unit, the predetermined history information is stored on the side of the first history storage unit and the second history storage unit that is not set as the storage target. A means for storing the history information corresponding to the occurrence of the predetermined event in both the first history storage means and the second history storage means until the predetermined amount or more is stored (management side CPU 112). Function for executing the process of step S2604 in step 2),
Equipped with
After the setting, the corresponding means is
After the setting value to be used is set by the setting unit, the predetermined history information is stored on the side of the first history storage unit and the second history storage unit that is not set as the storage target. A means for changing the storage object between the first history storage means and the second history storage means (a function of executing the processing of step S2607 in the management side CPU 112) when the specific amount or more is stored,
After the setting value to be used is set by the setting unit, the predetermined history information is stored on the side of the first history storage unit and the second history storage unit that is not set as the storage target. A means for erasing the history information on the side that has been set as the storage target of the first history storage means and the second history storage means when the specific amount is stored (step S2608 in the management-side CPU 112) Function that executes the process of
The gaming machine described in the feature C1 or C2, which is characterized by comprising:

According to the characteristic C3, until a specific amount of history information is newly stored in the history storage means, even if a new setting value to be used is set, it is stored before the setting. The history information is not deleted. As a result, even if a new setting value is set, it is possible to specify the management result of the game history in a predetermined period. Further, the effect can be brought about only by appropriately changing the history storage means for storing history information between the first history storage means and the second history storage means.

Feature C4. Using the history information stored on the side set as the storage target of the first history storage means and the second history storage means, the mode information corresponding to the result of the game in a predetermined period is derived. The gaming machine according to feature C3, which is provided with an information deriving means (a function of executing the process of step S2703 in the management-side CPU 112).

According to the characteristic C4, even if the history information is stored in both the first history storage unit and the second history storage unit due to the new setting of the set value, the mode in which the history information is used It is possible to appropriately derive the information.

Feature C5. Ball entry means (first operation port 33, second operation port 34) into which a game ball flowing down the game area can enter,
Information acquisition means (function for executing the process of step S401 in the main CPU 63) for acquiring special information based on the fact that a game ball has entered the ball entrance means,
An assignment determination unit that determines whether or not the special information corresponds to the assignment information (a function of the main CPU 63 that executes the processes of steps S503 and S504);
A privilege granting means (a step in the main CPU 63) for granting a privilege (opening/closing execution mode) to the player based on the result of the grant corresponding that the special information corresponds to the grant information in the grant determination. The function of executing the processing of S409 to step S412),
The gaming machine according to any one of the features C1 to C4, wherein the probability of being the assignment correspondence result in the assignment determination varies according to the setting value.

According to the characteristic C5, it is possible to change the probability of the assignment correspondence result in the so-called pachinko machine according to the set value.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features C1 to C5. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1-. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature D group>
Feature D1. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (a function for executing the setting value updating process in the main CPU 63),
Special execution means for executing special processing on the condition that the setting of the setting value to be used by the setting means has been executed in a special situation (in the third embodiment, monitoring of repeated changes in the management CPU 112) A function of executing processing, a function of executing monitoring processing of repeated changes in the main CPU 63 in the fourth embodiment, and a function of making negative determination in step S2106 of the management CPU 112 in the fifth embodiment).
A gaming machine characterized by being equipped with.

According to the characteristic D1, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player can use the more advantageous setting value as the usage target. Will be expected. In this case, the special process is executed on the condition that the new setting of the setting value to be used is executed in the special situation. This makes it possible to deal with a case where a new setting value is set in an unfavorable situation.

Feature D2. A feature D1 characterized in that the special execution means executes the special processing under at least one condition that the setting of the set value to be used by the setting means has been executed a specific number of times or more in the special situation. Gaming machine described in.

According to the characteristic D2, even if a new setting of the setting value to be used is executed in the special situation, the special process is not executed when the execution frequency is less than the specific frequency. As a result, it becomes possible to prevent the special process from being executed until the regular worker performs new setting of the set value less than the specified number of times in the special situation.

Feature D3. The special execution means, as the special situation, a situation in which a game is not being performed after the setting value to be used is set by the setting means, or the setting value to be used is set by the setting means. In a situation in which a game of a predetermined standard or more has not been played since the game was performed, the special processing is executed on the condition that the setting of the setting value to be used by the setting means is executed. The gaming machine described in the characteristic D1 or D2.

According to the feature D3, special processing is executed when a new setting of the setting value to be used is performed in a situation where no game is being played or a situation where a game is not substantially being played, When the act is performed, it becomes possible to deal with it.

Feature D4. The game machine according to any one of features D1 to D3, wherein the special execution means executes a notification process as the special process.

According to the characteristic D4, the notification process is executed under at least one condition that the new setting of the setting value to be used is executed in the special situation. As a result, when a new setting value is set in an unfavorable situation, it is possible to prompt the user to deal with it.

Feature D5. When a predetermined event occurs due to execution of a game, history storage execution means (a function of executing history setting processing in the management-side CPU 112) for storing history information of a game corresponding to the predetermined event in the history storage means (history memory 117) )When,
Corresponding to the result of the game in a predetermined period by using the history information stored in the history storage means, with at least one condition that the setting value to be used by the setting means is set. Information deriving means for deriving the mode information (the function of executing the process of step S1807 in the management CPU 112 in the third embodiment, the function of executing the process of step S2107 in the management CPU 112 in the fifth embodiment),
The gaming machine according to any one of the features D1 to D4.

According to the characteristic D5, when a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage means. As a result, it becomes possible to store and hold information for managing the number of occurrences or the frequency of occurrence of a predetermined event in the gaming machine, and it is preferable to manage the frequency of occurrence of the predetermined event by using this managed information. It becomes possible to do it. Further, since the history information is stored in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification.

In this case, when the setting value to be used is newly set, the mode information corresponding to the result of the game in a predetermined period is used by using the history information stored in the history storage means. Derived. As a result, it becomes possible to grasp the management result of the game history such as the frequency of occurrence of the predetermined event in the situation before the setting value is changed.

Feature D6. The special execution means, as at least one condition that the setting of the setting value to be used by the setting means has been executed in the special situation, as the special processing, derives the aspect information by the information deriving means. The gaming machine according to feature D5, which is characterized in that the game is not performed.

According to the feature D6, even if a new setting value to be used is set, the aspect information is not derived when the setting value is set in an unfavorable situation. This makes it possible to prevent the aspect information from being unnecessarily derived.

Feature D7. The gaming machine according to feature D5 or D6, characterized by further comprising mode information storage means (separate storage memory 171) for storing the mode information derived by the information derivation means.

According to the characteristic D7, the mode information corresponding to the result of the game in the predetermined period is utilized by using the history information stored in the history storage means when the setting value to be used is newly set. Is derived, the mode information is stored in the mode information storage means. As a result, even if the set value is changed, it is possible to grasp the management result of the game history in the situation before the set value is changed at an arbitrary timing thereafter.

Feature D8. The gaming machine according to Feature D7, wherein the aspect information storage means is capable of storing a plurality of the aspect information.

According to the characteristic D8, since it is possible to store a plurality of mode information in the mode information storage means, the management result of the game history in a plurality of periods is grasped with reference to the timing at which the new setting of the setting value is made. It becomes possible to do. Further, even if new setting of the set value is repeated under the situation where the game is not played, the aspect information derived by utilizing the history information of the situation where the game is substantially played is the aspect information storage means. It is possible to increase the possibility of remaining in.

Feature D9. The aspect information storage means can store a predetermined number of the aspect information,
Characteristic D7 characterized in that the special execution means executes the special processing when the setting value to be used by the setting means is set a number of times exceeding the predetermined number in the special situation. Or the gaming machine described in D8.

According to the characteristic D9, the set value is set in a situation in which the game is not played so that the mode information derived by using the history information of the situation in which the game is substantially played does not remain in the mode information storage means. When the new setting of is repeated, special processing is executed for it. This makes it possible to deal with the act.

Feature D10. Ball entry means (first operation port 33, second operation port 34) into which a game ball flowing down the game area can enter,
Information acquisition means (function for executing the process of step S401 in the main CPU 63) for acquiring special information based on the fact that a game ball has entered the ball entrance means,
An assignment determination unit that determines whether or not the special information corresponds to the assignment information (a function of the main CPU 63 that executes the processes of steps S503 and S504);
A privilege granting means (a step in the main CPU 63) for granting a privilege (opening/closing execution mode) to the player based on the result of the grant corresponding that the special information corresponds to the grant information in the grant determination. The function of executing the processing of S409 to step S412),
The gaming machine according to any one of the features D1 to D9, wherein the probability of being the grant corresponding result in the grant determination varies according to the set value.

According to the characteristic D10, it is possible to change the probability of the assignment correspondence result in the so-called pachinko machine according to the set value.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features D1 to D10. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, Any one or a plurality of configurations of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature E group>
Feature E1. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (a function for executing the setting value updating process in the main CPU 63),
When a predetermined event occurs due to execution of a game, history storage execution means (a function of executing history setting processing in the management-side CPU 112) for storing history information of a game corresponding to the predetermined event in the history storage means (history memory 117) )When,
Corresponding to the result of the game in a predetermined period by using the history information stored in the history storage means, with at least one condition that the setting value to be used by the setting means is set. Information deriving means for deriving the mode information (the function of executing the process of step S1807 in the management CPU 112 in the third embodiment, the function of executing the process of step S2107 in the management CPU 112 in the fifth embodiment),
A gaming machine characterized by being equipped with.

According to the characteristic E1, the setting value to be used is set from the setting values of the plurality of stages corresponding to the advantage degree of the player, so that the player sets the more advantageous setting value as the usage target. Will be expected. When a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage means. As a result, it becomes possible to store and hold information for managing the number of occurrences or the frequency of occurrence of a predetermined event in the gaming machine, and it is preferable to manage the frequency of occurrence of the predetermined event by using this managed information. It becomes possible to do it. Further, since the history information is stored in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification.

In this case, when the setting value to be used is newly set, the mode information corresponding to the result of the game in a predetermined period is used by using the history information stored in the history storage means. Derived. As a result, it becomes possible to grasp the management result of the game history such as the frequency of occurrence of the predetermined event in the situation before the setting value is changed.

Feature E2. The gaming machine according to feature E1, comprising a mode information storage unit (separate storage memory 171) that stores the mode information derived by the information derivation unit.

According to the feature E2, the mode information corresponding to the result of the game in the predetermined period is utilized by using the history information stored in the history storage means in response to the new setting of the setting value to be used. Is derived, the mode information is stored in the mode information storage means. As a result, even if the set value is changed, it is possible to grasp the management result of the game history in the situation before the set value is changed at an arbitrary timing thereafter.

Feature E3. The gaming machine according to feature E2, wherein the aspect information storage means is capable of storing a plurality of the aspect information.

According to the characteristic E3, since it is possible to store a plurality of aspect information in the aspect information storage means, the management result of the game history in a plurality of periods is grasped on the basis of the timing at which the new setting value is set. It becomes possible to do. Further, even if new setting of the set value is repeated under the situation where the game is not played, the aspect information derived by utilizing the history information of the situation where the game is substantially played is the aspect information storage means. It is possible to increase the possibility of remaining in.

Feature E4. The aspect information storage means can store a predetermined number of the aspect information,
The gaming machine is a means for executing special processing when the setting value to be used by the setting means is set a predetermined number of times under a predetermined condition (in the third embodiment, in the management CPU 112). The gaming machine according to the feature E2 or E3, which is provided with a function of executing monitoring processing of repeated changes, a function of executing monitoring processing of repeated changes in the main CPU 63 in the fourth embodiment).

According to the characteristic E4, the set value is set in a situation where the game is not played so that the aspect information derived by using the history information of the situation in which the game is substantially played does not remain in the aspect information storage means. When the new setting of is repeated, special processing is executed for it. This makes it possible to deal with the act.

Feature E5. The gaming machine according to any one of features E1 to E4, wherein the information deriving unit derives the aspect information when the history storage unit stores a predetermined amount or more of the history information. ..

According to the feature E5, the aspect information is derived when the history storage means stores a predetermined amount or more of the predetermined history information, and thus it is possible to prevent the situation information from being unnecessarily derived. Become.

Feature E6. Ball entry means (first operation port 33, second operation port 34) into which a game ball flowing down the game area can enter,
Information acquisition means (function for executing the process of step S401 in the main CPU 63) for acquiring special information based on the fact that a game ball has entered the ball entrance means,
An assignment determination unit that determines whether or not the special information corresponds to the assignment information (a function of the main CPU 63 that executes the processes of steps S503 and S504);
A privilege granting means (a step in the main CPU 63) for granting a privilege (opening/closing execution mode) to the player based on the result of the grant corresponding that the special information corresponds to the grant information in the grant determination. The function of executing the processing of S409 to step S412),
The gaming machine according to any one of features E1 to E5, characterized in that the probability of being the assignment correspondence result in the assignment determination varies according to the setting value.

According to the feature E6, it is possible to change the probability of the assignment correspondence result in the so-called pachinko machine according to the set value.

In addition, with respect to the configurations of the features E1 to E6, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the inventions related to the characteristic A group, the characteristic B group, the characteristic C group, the characteristic D group, and the characteristic E group, it is possible to solve the following problems.

Pachinko machines and slot machines are known as game machines. For example, in a pachinko machine, the game machine front face section is provided with a dish storage section for storing the game balls given to the player, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, it is necessary to manage the gaming machine appropriately, and there is still room for improvement in this respect.

<Feature F group>
Feature F1. Ball entry means (first operation port 33, second operation port 34) into which a game ball flowing down the game area can enter,
Information acquisition means (function for executing the process of step S401 in the main CPU 63) for acquiring special information based on the fact that a game ball has entered the ball entrance means,
An assignment determination unit that determines whether or not the special information corresponds to the assignment information (a function of the main CPU 63 that executes the processes of steps S503 and S504);
A privilege granting means (a step in the main CPU 63) for granting a privilege (opening/closing execution mode) to the player based on the result of the grant corresponding that the special information corresponds to the grant information in the grant determination. A function of executing the processing of S409 to step S412),
Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (a function for executing the setting value updating process in the main CPU 63),
Equipped with
The grant determination means has a high-probability mode and a low-probability mode so that the probability of the grant-corresponding result is relatively high or low, as the mode of the grant determination.
A gaming machine characterized in that the probability of being the assignment correspondence result varies at least in the low probability mode according to the set value.

According to the feature F1, it is possible to vary the probability of the assignment correspondence result in at least the low probability mode in the so-called pachinko machine according to the set value. As a result, even in the case of a single gaming machine, it is possible to cause a situation in which the probability of being the assignment correspondence result in the low probability mode is advantageous or disadvantageous. Therefore, it becomes possible to improve the interest of the game.

Feature F2. The gaming machine according to feature F1, wherein the probability of the assignment correspondence result in the high probability mode does not change according to the set value.

According to the feature F2, the probability of the assignment correspondence result in the low probability mode is changed according to the set value, while the probability of the assignment correspondence result in the high probability mode is not changed according to the set value. By doing so, it becomes possible to limit the influence of the set value to the situation in the low probability mode.

Feature F3. There are several types of benefits,
The amusement machine according to the characteristic F1 or F2, wherein the selection mode of the privilege does not change according to the set value.

According to the feature F3, the probability of the assignment correspondence result in the low probability mode is changed according to the set value, while the privilege selection mode is not changed according to the set value, so that the influence of the set value is affected. Can be restricted to situations in the low probability mode.

In addition, with respect to the configurations of the features F1 to F3, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the characteristic group F, it is possible to solve the following problems.

Pachinko machines and slot machines are known as game machines. For example, in a pachinko machine, the game machine front face section is provided with a dish storage section for storing the game balls given to the player, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, it is necessary to improve the interest of the game, and there is still room for improvement in this respect.

<Feature G group>
Features G1. When a predetermined event occurs due to execution of a game, history storage execution means (a function of executing history setting processing in the management-side CPU 112) for storing history information of a game corresponding to the predetermined event in the history storage means (history memory 117) )When,
Information derivation means for deriving mode information corresponding to a result of a game in a predetermined period by using the history information stored in the history storage means (steps S1402 to S1412 in the management CPU 112 in the first embodiment). The function of executing the processing of step S1807 in the management-side CPU 112 in the third embodiment, the function of executing the processing of step S2107 in the management-side CPU 112 in the fifth embodiment).
Information display means (in the first to tenth embodiments, first to third notification display devices 69a to 69c, and eleventh to tenth) so that a display corresponding to the aspect information derived by the information deriving means is performed. In the fourteenth embodiment, first information display control means (a function of executing display processing in the management-side CPU 112) for controlling display of the first to fourth notification display devices 201 to 204),
Second information display control means (steps S202 and S208 in the main CPU 63 in the first to tenth embodiments) for controlling display of the information display means so that display corresponding to different information different from the aspect information is performed. Function for executing the processing of step S3101, step S3103 and step S3109 in the main CPU 63 in the eleventh embodiment, step S3201, step S3202, step S3204 in the main CPU 63 in the twelfth embodiment. And a function of executing the process of step S3210, a function of executing an abnormality display process in the main CPU 63 in the thirteenth embodiment),
A gaming machine characterized by being equipped with.

According to the characteristic G1, when the predetermined event occurs, the history information corresponding to the predetermined event is stored in the history storage means. As a result, it becomes possible to store and hold information for managing the number of occurrences or the frequency of occurrence of a predetermined event in the gaming machine, and it is preferable to manage the frequency of occurrence of the predetermined event by using this managed information. It becomes possible to do it. Further, since the history information is stored in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, using the history information stored in the history storage means, the form information corresponding to the result of the game in the predetermined period is derived. Then, the display corresponding to the aspect information is performed by the information display means. Thereby, it becomes possible to grasp the management result of the game history such as the frequency of occurrence of the predetermined event. Further, in the information display means, not only the display corresponding to the aspect information but also the display corresponding to the different information is performed. This makes it possible to effectively use the information display means.

Features G2. Characteristic G1 characterized in that a period during which a display corresponding to the aspect information is performed on the information display unit and a period during which a display corresponding to the different information is performed on the information display unit are distinguished. Amusement machine.

According to the feature G2, which of the display corresponding to the aspect information and the display corresponding to the different information is performed on the information display means by grasping the situation in which the display is performed on the information display means. Can be specified.

Features G3. The second information display control means displays the display corresponding to the different information by controlling the display of the information display means so as to be a display mode different from the display mode when the display corresponding to the mode information is performed. The gaming machine described in the feature G1 or G2, which is characterized by being performed.

According to the feature G3, by grasping the display mode of the information display means, it is possible to specify which of the display corresponding to the mode information and the display corresponding to the different information is being performed on the information display means. It will be possible.

Features G4. As the information display means, individual information display means (in the first to tenth embodiments, first to third notification display devices 69a to 69c, and eleventh to fourteenth, respectively) capable of performing a plurality of types of display respectively. In the embodiment, the gaming machine according to any one of the features G1 to G3, characterized in that a plurality of first to fourth notification display devices 201 to 204) are provided.

According to the feature G4, it is possible to display a wide variety of aspect information by performing the display corresponding to the aspect information using the plurality of individual information display means. In addition, the presence of the plurality of individual information display means makes it possible to greatly differ the display mode between when the display corresponding to the mode information is performed and when the display corresponding to the different information is performed. ..

Features G5. The second information display control means, when performing the display corresponding to the different information, does not become a non-display state when a display corresponding to the aspect information is performed among the plurality of individual information display means. Information display means (first notification display device 69a and second notification display device 69b in the first to tenth embodiments, first notification display device 201, second notification display device in the eleventh and twelfth embodiments) The display device 202 and the third notification display device 203, and in the thirteenth embodiment, the first notification display device 201 and the second notification display device 202) are set in a non-display state. Gaming machine described in.

According to the characteristic G5, when the display corresponding to the aspect information is performed, the predetermined individual information display unit that is not in the non-display state is in the non-display state when the display corresponding to the different information is performed. With this, it is possible to clearly identify which of the display corresponding to the mode information and the display corresponding to the different information is performed only by grasping the type of the individual information display means in the non-display state. Is possible.

Features G6. The second information display control means, when the display corresponding to the different information is performed, the specific individual information display means (the first individual information display means that is in a display state when the aspect information is displayed among the plurality of individual information display means (first In the first to tenth embodiments, the third notification display device 69c, in the eleventh and twelfth embodiments, the fourth notification display device 204, and in the thirteenth embodiment, the third notification display device 203 and the fourth notification. Display device 204) for display,
The display content of the specific individual information display means when the display corresponding to the different information is performed may be displayed on the specific individual information display means when the display corresponding to the aspect information is performed. The gaming machine described in G5.

According to the feature G6, the display content that can be displayed when the display corresponding to the aspect information is performed on the specific individual information display means can be displayed even when the display corresponding to the different information is performed. It is possible to prevent the display contents from being restricted when the display corresponding to the information is performed. Even if the specific individual information display means has the same display content as described above, it does not become the non-display state when the display corresponding to the mode information is provided with the configuration of the above feature G5. When a predetermined individual information display means displays a display corresponding to different information, it is in a non-display state, so that it is possible to specify which display is being performed on the plurality of individual information display means.

Features G7. The gaming machine according to feature G5 or G6, wherein the first information display control means sets each of the plurality of individual information display means in a display state when a display corresponding to the aspect information is performed.

According to the feature G7, when the display corresponding to the aspect information is performed, each of the plurality of individual information display units is in the display state, and thus the predetermined individual information display unit corresponds to the other information in the non-display state. It is possible to clearly distinguish it from the case where it is displayed.

Features G8. The first information display control means sequentially changes the display of the mode information on the information display means, and even when the display of the mode information is changed, the predetermined individual information display means is in a non-display state. The gaming machine according to any one of the features G5 to G7, which is characterized in that the gaming machine is not maintained.

According to the characteristic G8, when the display corresponding to the aspect information is performed, the predetermined individual information display means is not maintained in the non-display state. With this, regardless of the timing of confirming the plurality of individual information display means, it is possible to specify which of the display corresponding to the aspect information and the display corresponding to the different information is performed in the plurality of individual information display means. Is possible.

Features G9. The second information display control means is one specific individual information display means among the plurality of individual information display means (in the first to tenth embodiments, the third notification display device 69c, eleventh and twelfth). In any of the features G5 to G8, the fourth notification display device 204) displays a display corresponding to the different information, and the remaining individual information display means is in a non-display state. The gaming machine described in 1.

According to the characteristic G9, when the display corresponding to the different information is performed, only one individual information display unit is in the display state, so that it is easy to understand whether or not the display corresponding to the different information is performed. Become.

Feature G10. A plurality of the individual information display means are arranged in a predetermined direction,
The gaming machine according to feature G9, wherein the specific individual information display means is present at an end of the plurality of individual information display means arranged in the predetermined direction in the predetermined direction.

According to the characteristic G10, since one individual information display means for displaying the different information is present at the end portion in the predetermined direction, it is grasped whether or not the display corresponding to the different information is performed. Easier to do.

Feature G11. The first information display control means is an individual information display means of a type display target that is a part of the plurality of individual information display means (in the first to tenth embodiments, the first notification display device 69a, the eleventh notification display device). In the fourteenth embodiment, the first notification display device 201 and the second notification display device 202) are configured to perform a display corresponding to the type of the aspect information to be displayed, and a plurality of the individual information display means. The individual information display means of the result display target that is a part of the second display device 69b and the third notification display device 69c in the first to tenth embodiments, and the first information display device 69c in the eleventh to fourteenth embodiments. The display corresponding to the contents of the aspect information to be displayed is displayed on the third notification display device 203 and the fourth notification display device 204),
The gaming machine according to any one of features G5 to G10, wherein the predetermined individual information display unit corresponds to the individual information display unit of the type display target.

According to the characteristic G11, when the display corresponding to the aspect information is performed, the individual information display unit for the type display target performs the display corresponding to the type of the aspect information to be displayed and the individual information display for the result display target. The means performs a display corresponding to the content of the mode information to be displayed. This makes it easier to understand the aspect information that is the display target. In this case, when the display corresponding to the different information is performed, the individual information display means of the type display target is in the non-display state, which means that the type display non-display state corresponds to the different information. It becomes easier to understand if the different information is displayed.

Features G12. The information display unit has a plurality of unit light emitting units (display segments 201a to 201g, 202a to 202g), and performs a predetermined display by a combination of the unit light emitting units in the light emitting state among the plurality of unit light emitting units. Is possible configuration,
The second information display control means responds to the different information by setting a unit light emitting unit that can be in a light emitting state when a display corresponding to the aspect information is performed among the plurality of unit light emitting units to a light emitting state. The display is performed, and the combination of the unit light emitting units that are in a light emitting state when the display corresponding to the different information is performed does not exist when the display corresponding to the aspect information is performed. The gaming machine according to any one of the features G1 to G11, which is a combination.

According to the feature G12, when the display corresponding to the aspect information is performed, the display corresponding to the different information is performed by setting the unit light-emitting unit that is in the light emitting state to the light emitting state to perform the display corresponding to the aspect information. In order to diversify, it is possible to prevent the contents of display corresponding to the aspect information from being restricted as much as possible. On the other hand, the combination of the unit light emitting units that are in the light emitting state when the display corresponding to the different information is performed is a combination that does not exist when the display corresponding to the aspect information is performed. This makes it possible to grasp which of the display corresponding to the mode information and the display corresponding to the different information is being performed by grasping the combination of the unit light emitting units which are in the light emitting state.

Features G13. There are a plurality of display modes of the display corresponding to the mode information in the information display means,
The game according to the feature G12, wherein there is no unit light emitting unit that does not enter the light emitting state even if all the displays corresponding to the aspect information of the plurality of aspects are present in the plurality of unit light emitting units. Machine.

According to the feature G13, when the display corresponding to the aspect information is performed, the unit light-emitting units of an arbitrary combination are set to the light emitting state, so that the aspect corresponding to the aspect information can be diversified. It is possible to prevent the contents of the display corresponding to the information from being restricted as much as possible.

Features G14. Specific individual information display means which is the information display means (third notification display device 69c in the first to tenth embodiments, fourth notification display device 204, thirteenth in the eleventh and twelfth embodiments). In the embodiment, a plurality of individual information display means including the third notification display device 203 and the fourth notification display device 204) are provided,
The second information display control means, when the display corresponding to the different information is performed, does not become the non-display state when the display corresponding to the aspect information is performed among the plurality of individual information display means. Information display means (first notification display device 69a and second notification display device 69b in the first to tenth embodiments, first notification display device 201, second notification display device in the eleventh and twelfth embodiments) The display device 202 and the third notification display device 203, and in the thirteenth embodiment, the first notification display device 201 and the second notification display device 202) are set in a non-display state. Or a game machine according to G13.

According to the feature G14, when the display corresponding to the aspect information is performed, the predetermined individual information display unit that is not in the non-display state is in the non-display state when the display corresponding to the different information is performed. With this, it is possible to clearly identify which of the display corresponding to the mode information and the display corresponding to the different information is performed only by grasping the type of the individual information display means in the non-display state. Is possible.

Feature G15. A setting means (a function of executing a set value update process in the main CPU 63) for setting a set value to be used from a plurality of set values corresponding to the player's advantage is provided.
The gaming machine according to any one of features G1 to G14, wherein the second information display control means causes a display corresponding to the different information in a situation where the setting value can be changed.

According to the feature G15, it becomes possible to use the information display means for displaying the aspect information as the display means for notifying that the setting value can be changed.

Feature G16. The gaming machine according to feature G15, wherein the second information display control means causes the display of information corresponding to the setting value currently selected as the display corresponding to the different information.

According to the feature G16, it becomes possible to use the information display means for displaying the mode information as the display means for displaying the set value being changed.

Feature G17. The gaming machine according to any one of features G1 to G16, wherein the second information display control means causes a display corresponding to an abnormal state of the gaming machine as a display corresponding to the different information.

According to the feature G17, it becomes possible to use the information display means for performing the display corresponding to the aspect information as the display means for performing the display corresponding to the abnormal state of the gaming machine.

Features G18. The second information display control means, when the display corresponding to the abnormal state is performed in a situation where the abnormal state has not occurred, causes the display corresponding to that the abnormal state has not occurred. The gaming machine described in G17.

According to the feature G18, it is possible to clearly specify whether or not the abnormal state has occurred by checking the information display means.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features G1 to G18. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, Any one or a plurality of configurations of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature H group>
Features H1. When a predetermined event occurs due to execution of a game, history storage execution means (a function of executing history setting processing in the management-side CPU 112) for storing history information of a game corresponding to the predetermined event in the history storage means (history memory 117) )When,
Information derivation means for deriving mode information corresponding to a result of a game in a predetermined period by using the history information stored in the history storage means (steps S1402 to S1412 in the management CPU 112 in the first embodiment). The function of executing the processing of step S1807 in the management-side CPU 112 in the third embodiment, the function of executing the processing of step S2107 in the management-side CPU 112 in the fifth embodiment).
Information display means (in the first to tenth embodiments, first to third notification display devices 69a to 69c, and eleventh to tenth) so that a display corresponding to the aspect information derived by the information deriving means is performed. In the fourteenth embodiment, first information display control means (a function of executing display processing in the management-side CPU 112) for controlling display of the first to fourth notification display devices 201 to 204),
Second information display control means (steps S202 and S208 in the main CPU 63 in the first to tenth embodiments) for controlling display of the information display means so that display corresponding to different information different from the aspect information is performed. Function for executing the processing of step S3101, step S3103 and step S3109 in the main CPU 63 in the eleventh embodiment, step S3201, step S3202, step S3204 in the main CPU 63 in the twelfth embodiment. And a function of executing the process of step S3210, a function of executing an abnormality display process in the main CPU 63 in the thirteenth embodiment),
Equipped with
The information display unit has a plurality of unit light emitting units (display segments 201a to 201g, 202a to 202g), and performs a predetermined display by a combination of the unit light emitting units in the light emitting state among the plurality of unit light emitting units. Is possible configuration,
The second information display control means responds to the different information by setting a unit light emitting unit that can be in a light emitting state when a display corresponding to the aspect information is performed among the plurality of unit light emitting units to a light emitting state. The display is performed, and the combination of the unit light emitting units that are in a light emitting state when the display corresponding to the different information is performed does not exist when the display corresponding to the aspect information is performed. A game machine characterized by being a combination.

According to the feature H1, when the predetermined event occurs, the history information corresponding to the predetermined event is stored in the history storage means. As a result, it becomes possible to store and hold information for managing the number of occurrences or the frequency of occurrence of a predetermined event in the gaming machine, and it is preferable to manage the frequency of occurrence of the predetermined event by using this managed information. It becomes possible to do it. Further, since the history information is stored in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, using the history information stored in the history storage means, the form information corresponding to the result of the game in the predetermined period is derived. Then, the display corresponding to the aspect information is performed by the information display means. Thereby, it becomes possible to grasp the management result of the game history such as the frequency of occurrence of the predetermined event. Further, in the information display means, not only the display corresponding to the aspect information but also the display corresponding to the different information is performed. This makes it possible to effectively use the information display means.

In addition, when the display corresponding to the aspect information is performed, the unit light-emitting unit that can be in the light emitting state is set to the light emitting state, and the display corresponding to the different information is performed, thereby diversifying the display corresponding to the aspect information. For this purpose, it is possible to prevent the contents of display corresponding to the aspect information from being restricted as much as possible. On the other hand, the combination of the unit light emitting units that are in the light emitting state when the display corresponding to the different information is performed is a combination that does not exist when the display corresponding to the aspect information is performed. This makes it possible to grasp which of the display corresponding to the mode information and the display corresponding to the different information is being performed by grasping the combination of the unit light emitting units which are in the light emitting state.

Features H2. There are a plurality of display modes of the display corresponding to the mode information in the information display means,
The game according to the feature H1 characterized in that there is no unit light emitting unit in the plurality of unit light emitting units that does not become in a light emitting state even if all the displays corresponding to the aspect information of the plurality of aspects are performed. Machine.

According to the characteristic H2, when the display corresponding to the mode information is performed, the unit light-emitting units of an arbitrary combination are set to the light emitting state. Therefore, in order to diversify the display corresponding to the mode information, It is possible to prevent the contents of the display corresponding to the information from being restricted as much as possible.

Features H3. Specific individual information display means which is the information display means (third notification display device 69c in the first to tenth embodiments, fourth notification display device 204, thirteenth in the eleventh and twelfth embodiments). In the embodiment, a plurality of individual information display means including the third notification display device 203 and the fourth notification display device 204) are provided,
The second information display control means, when the display corresponding to the different information is performed, does not become the non-display state when the display corresponding to the aspect information is performed among the plurality of individual information display means. Information display means (first notification display device 69a and second notification display device 69b in the first to tenth embodiments, first notification display device 201, second notification display device in the eleventh and twelfth embodiments) Characteristic H1 characterized in that the display device 202 and the third notification display device 203, and in the thirteenth embodiment, the first notification display device 201 and the second notification display device 202) are in a non-display state. Or the gaming machine described in H2.

According to the feature H3, when the display corresponding to the aspect information is performed, the predetermined individual information display unit that is not in the non-display state is in the non-display state when the display corresponding to the different information is performed. With this, it is possible to clearly identify which of the display corresponding to the mode information and the display corresponding to the different information is performed only by grasping the type of the individual information display means in the non-display state. Is possible.

Features H4. The gaming machine according to feature H3, wherein the first information display control means sets each of the plurality of individual information display means in a display state when a display corresponding to the aspect information is performed.

According to the feature H4, when the display corresponding to the aspect information is performed, each of the plurality of individual information display units is in the display state, and thus the predetermined individual information display unit corresponds to the other information in the non-display state. It is possible to clearly distinguish it from the case where it is displayed.

Features H5. The first information display control means sequentially changes the display of the mode information on the information display means, and even when the display of the mode information is changed, the predetermined individual information display means is in a non-display state. The gaming machine according to the feature H3 or H4, characterized in that the gaming machine is not maintained at.

According to the feature H5, the predetermined individual information display means is not maintained in the non-display state when the display corresponding to the aspect information is performed. With this, regardless of the timing of confirming the plurality of individual information display means, it is possible to specify which of the display corresponding to the aspect information and the display corresponding to the different information is performed in the plurality of individual information display means. Is possible.

Features H6. A setting means (a function of executing a set value update process in the main CPU 63) for setting a set value to be used from a plurality of set values corresponding to the player's advantage is provided.
The gaming machine according to any one of features H1 to H5, wherein the second information display control means causes a display corresponding to the different information in a situation where the setting value can be changed.

According to the feature H6, it is possible to use the information display means for performing the display corresponding to the aspect information as the display means for notifying that the setting value can be changed.

Features H7. The gaming machine according to Feature H6, wherein the second information display control means causes the display of information corresponding to the setting value currently selected as the display corresponding to the different information.

According to the feature H7, it is possible to use the information display means for performing the display corresponding to the aspect information as the display means for displaying the set value being changed.

In addition, with respect to the configuration of the features H1 to H7, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature group I>
Feature I1. When a predetermined event occurs due to execution of a game, history storage execution means (a function of executing history setting processing in the management-side CPU 112) for storing history information of a game corresponding to the predetermined event in the history storage means (history memory 117) )When,
Information derivation means for deriving mode information corresponding to a result of a game in a predetermined period by using the history information stored in the history storage means (steps S1402 to S1412 in the management CPU 112 in the first embodiment). The function of executing the processing of step S1807 in the management-side CPU 112 in the third embodiment, the function of executing the processing of step S2107 in the management-side CPU 112 in the fifth embodiment).
First information display control means (management side) for controlling display of the information display means (first to fourth notification display devices 201 to 204) so that the display corresponding to the aspect information derived by the information deriving means is performed. A function of executing display processing in the CPU 112),
Second information display control means (a function of executing processing for abnormality display in the main CPU 63) for controlling display of the information display means so that a display corresponding to an abnormal state of the gaming machine is performed,
A gaming machine characterized by being equipped with.

According to the characteristic I1, when the predetermined event occurs, the history information corresponding to the predetermined event is stored in the history storage means. As a result, it becomes possible to store and hold information for managing the number of occurrences or the frequency of occurrence of a predetermined event in the gaming machine, and it is preferable to manage the frequency of occurrence of the predetermined event by using this managed information. It becomes possible to do it. Further, since the history information is stored in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, using the history information stored in the history storage means, the form information corresponding to the result of the game in the predetermined period is derived. Then, the display corresponding to the aspect information is performed by the information display means. Thereby, it becomes possible to grasp the management result of the game history such as the frequency of occurrence of the predetermined event. In addition, not only the display corresponding to the mode information but also the display corresponding to the abnormal state of the gaming machine is performed on the information display means. This makes it possible to effectively use the information display means.

Feature I2. The second information display control means, when the display corresponding to the abnormal state is performed in a situation where the abnormal state has not occurred, causes the display corresponding to that the abnormal state has not occurred. The gaming machine described in Feature I1.

According to the characteristic I2, it is possible to clearly specify whether or not the abnormal state has occurred by checking the information display means.

Feature I3. Characteristic I1 or I2 characterized in that a period during which a display corresponding to the aspect information is performed on the information display unit is distinguished from a period during which a display corresponding to the abnormal state is performed on the information display unit. The game machine described.

According to the feature I3, which of the display corresponding to the mode information and the display corresponding to the abnormal state is performed on the information display unit by grasping the situation in which the display is performed on the information display unit. Can be specified.

Feature I4. The second information display control means displays the display corresponding to the abnormal state by controlling the display of the information display means so as to be a display mode different from the display mode when the display corresponding to the mode information is performed. The gaming machine described in the feature G1 or G2, which is characterized by being performed.

According to the characteristic I4, by grasping the display mode of the information display means, it is possible to specify which of the display corresponding to the mode information and the display corresponding to the abnormal state is being performed on the information display means. It will be possible.

Feature I5. As the information display means, a plurality of individual information display means (first to fourth notification display devices 201 to 204) capable of performing a plurality of types of display are provided, respectively, and features I1 to I4 The gaming machine according to any one of 1.

According to the feature I5, it is possible to display a wide variety of aspect information by performing the display corresponding to the aspect information using the plurality of individual information display means. In addition, the presence of the plurality of individual information display means makes it possible to greatly differ the display mode between when the display corresponding to the mode information is performed and when the display corresponding to the abnormal state is performed. ..

Feature I6. The second information display control means, when performing the display corresponding to the abnormal state, does not become a non-display state when a display corresponding to the aspect information is performed among the plurality of individual information display means The gaming machine according to feature I5, characterized in that the information display means (the first notification display device 201 and the second notification display device 202) is in a non-display state.

According to the feature I6, the predetermined individual information display means, which is not in the non-display state when the display corresponding to the mode information is performed, is in the non-display state when the display corresponding to the abnormal state is performed. With this, it is possible to clearly identify which of the display corresponding to the mode information and the display corresponding to the abnormal state is performed, only by grasping the type of the individual information display means in the non-display state. Is possible.

Features I7. The second information display control means, when the display corresponding to the abnormal state is to be performed, the specific individual information display means (the first individual information display means to be in the display state when the aspect information is displayed among the plurality of individual information display means (first 3 notification display device 203 and fourth notification display device 204) are brought into a display state,
The display content of the specific individual information display means when the display corresponding to the abnormal state is performed may be displayed on the specific individual information display means when the display corresponding to the aspect information is performed. The gaming machine described in Feature I6.

According to the feature I7, the display content that can be displayed when the display corresponding to the mode information is displayed on the specific individual information display means can be displayed even when the display corresponding to the abnormal state is displayed. It is possible to prevent the display contents from being restricted when the display corresponding to the information is performed. Even if the specific individual information display means has the same display content as described above, it does not become the non-display state when the display corresponding to the aspect information is provided with the configuration of the characteristic I7. When a predetermined individual information display means displays a display corresponding to an abnormal state, it is in a non-display state, and therefore it is possible to specify which display is being performed on the plurality of individual information display means.

Feature I8. The game machine according to feature I6 or I7, wherein the first information display control means sets each of the plurality of individual information display means in a display state when performing display corresponding to the aspect information.

According to the characteristic I8, when the display corresponding to the aspect information is performed, each of the plurality of individual information display units is in the display state, and thus the predetermined individual information display unit corresponds to the abnormal state in which the predetermined individual information display unit is in the non-display state. It is possible to clearly distinguish it from the case where it is displayed.

Feature I9. The first information display control means sequentially changes the display of the mode information on the information display means, and even when the display of the mode information is changed, the predetermined individual information display means is in a non-display state. The gaming machine according to any one of the features I6 to I8, characterized in that the gaming machine is not maintained at.

According to the feature I9, when the display corresponding to the aspect information is performed, the predetermined individual information display unit is not maintained in the non-display state. This makes it possible to identify which of the display corresponding to the mode information and the display corresponding to the abnormal state is being performed on the plurality of individual information display means regardless of the timing at which the plurality of individual information display means are confirmed. Is possible.

In addition, with respect to the configurations of the features I1 to I9, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature J group>
Features J1. When a predetermined event occurs due to execution of a game, history storage execution means (a function of executing history setting processing in the management-side CPU 112) for storing history information of a game corresponding to the predetermined event in the history storage means (history memory 117) )When,
Information derivation means for deriving mode information corresponding to a result of a game in a predetermined period by using the history information stored in the history storage means (steps S1402 to S1412 in the management CPU 112 in the first embodiment). The function of executing the processing of step S1807 in the management-side CPU 112 in the third embodiment, the function of executing the processing of step S2107 in the management-side CPU 112 in the fifth embodiment).
Information display means (in the first to tenth embodiments, first to third notification display devices 69a to 69c, and eleventh to tenth) so that a display corresponding to the aspect information derived by the information deriving means is performed. In the fourteenth embodiment, first information display control means (a function of executing display processing in the management-side CPU 112) for controlling display of the first to fourth notification display devices 201 to 204),
Equipped with
The first information display control means sequentially changes the display corresponding to the aspect information on the information display means, and the information display means does not display even when the display corresponding to the aspect information is changed. A game machine characterized in that it is not maintained in a state.

According to the feature J1, when the predetermined event occurs, the history information corresponding to the predetermined event is stored in the history storage means. As a result, it becomes possible to store and hold information for managing the number of occurrences or the frequency of occurrence of a predetermined event in the gaming machine, and it is preferable to manage the frequency of occurrence of the predetermined event by using this managed information. It becomes possible to do it. Further, since the history information is stored in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, using the history information stored in the history storage means, the form information corresponding to the result of the game in the predetermined period is derived. Then, the display corresponding to the aspect information is performed by the information display means. Thereby, it becomes possible to grasp the management result of the game history such as the frequency of occurrence of the predetermined event. Further, when the display corresponding to the aspect information is performed, the information display means is not maintained in the non-display state. This makes it possible to specify the display corresponding to the aspect information regardless of the timing when the information display means is confirmed.

Features J2. As the information display means, individual information display means (in the first to tenth embodiments, first to third notification display devices 69a to 69c, and eleventh to fourteenth, respectively) capable of performing a plurality of types of display respectively. In the above embodiment, the gaming machine according to feature J1 is provided with a plurality of first to fourth notification display devices 201 to 204).

According to the feature J2, it is possible to display a wide variety of aspect information by performing the display corresponding to the aspect information using the plurality of individual information display means.

Features J3. The gaming machine according to feature J2, wherein the first information display control means sets each of the plurality of individual information display means in a display state when a display corresponding to the aspect information is performed.

According to the feature J3, when the display corresponding to the mode information is performed, each of the plurality of individual information display means is in the display state, and even when the display corresponding to the mode information is changed, the display state is changed. Maintained. This makes it easier to understand the aspect information.

Features J4. The first information display control means is a part of the plurality of individual information display means, which is a type display target individual information display means (in the first to tenth embodiments, the first notification display device 69a and the eleventh display device). In the fourteenth embodiment, the first notification display device 201 and the second notification display device 202) are configured to perform a display corresponding to the type of the aspect information to be displayed, and a plurality of the individual information display means. The individual information display means of the result display target which is a part of the second display device 69b and the third notification display device 69c in the first to tenth embodiments, and the first information display device 69c in the eleventh to fourteenth embodiments. The gaming machine according to feature J2 or J3, characterized in that a display corresponding to the contents of the aspect information to be displayed is performed on the third notification display device 203 and the fourth notification display device 204).

According to the feature J4, when the display corresponding to the aspect information is performed, the individual information display unit for the type display target performs the display corresponding to the type of the aspect information to be displayed and the individual information display for the result display target. A display corresponding to the content of the mode information to be displayed is performed by the means. This makes it easier to understand the aspect information that is the display target.

For the configurations of the features J1 to J4, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic K group>
Features K1. When a predetermined event occurs due to execution of a game, history storage execution means (a function of executing history setting processing in the management-side CPU 112) for storing history information of a game corresponding to the predetermined event in the history storage means (history memory 117) ),
The history storage execution means is a means for preventing the history information from being stored in the history storage means even if the predetermined event occurs (a function of making a negative determination in step S3501 in the main CPU 63 in the case of a restricted situation). ) Is equipped with a gaming machine.

According to the characteristic K1, when the predetermined event occurs, the history information corresponding to the predetermined event is stored in the history storage means. As a result, it becomes possible to store and hold information for managing the number of occurrences or the frequency of occurrence of a predetermined event in the gaming machine, and it is preferable to manage the frequency of occurrence of the predetermined event by using this managed information. It becomes possible to do it. Further, since the history information is stored in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, in the restricted situation, the history information is not stored even if a predetermined event occurs, so that it is possible to prevent the history information from being stored in a situation where it is not preferable to store the history information. ..

Features K2. The gaming machine according to feature K1, wherein the restricted status can occur as a status from when the supply of operating power to the history storage execution means is started to when a restriction release event occurs.

According to the characteristic K2, it is possible to prevent the occurrence of a predetermined event due to the operation check immediately after the start of supplying the operating power from being stored as history information.

Features K3. A means for setting the restriction status when the supply of the operating power to the history storage executing means is started and the restriction condition is satisfied (function of executing the process of step S3610 in the main CPU 63); ,
Means for not setting the limited condition when the supply of operating power to the history storage executing means is started and the limiting condition is not satisfied (function of executing the process of step S3621 in the main CPU 63) When,
The gaming machine described in the feature K2, which is provided with.

According to the characteristic K3, there are a case where the restriction condition is set and a case where the restriction condition is not set depending on whether or not the restriction condition is satisfied. This makes it possible to prevent the restriction status from being set as necessary.

Features K4. It is characterized in that the restriction situation can occur as a situation from when the supply of the operating power to the history storage executing means is started to when the number of discharged game balls from the game area becomes a predetermined reference number or more. The gaming machine according to any one of K1 to K3.

According to the characteristic K4, it is possible to prevent the history information from being stored until the number of discharged game balls from the game area reaches or exceeds the predetermined reference number after the supply of the operating power is started.

Features K5. When a predetermined event occurs due to the execution of the game, the history information of the game corresponding to the predetermined event is stored in the history storage means (normal counter area 231, opening/closing execution mode counter area 232, high frequency support mode counter area 233). History storing execution means for storing (a function of executing a normal ball management process in the main CPU 63, a ball management process in the open/close execution mode, and a ball management process in the high-frequency support mode);
Information derivation means (a function for executing the process of step S4208 in the main CPU 63) for deriving mode information corresponding to the result of the game in a predetermined period using the history information stored in the history storage means,
Equipped with
The game machine characterized in that the information deriving means does not derive the mode information when the status is restricted.

According to the characteristic K5, when the predetermined event occurs, the history information corresponding to the predetermined event is stored in the history storage means. As a result, it becomes possible to store and hold information for managing the number of occurrences or the frequency of occurrence of a predetermined event in the gaming machine, and it is preferable to manage the frequency of occurrence of the predetermined event by using this managed information. It becomes possible to do it. Further, since the history information is stored in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, using the history information stored in the history storage means, the form information corresponding to the result of the game in the predetermined period is derived. Thereby, it becomes possible to grasp the management result of the game history such as the frequency of occurrence of the predetermined event. Further, in the restricted situation, the aspect information is not derived even if a predetermined event occurs, so it is possible to prevent the aspect information from being derived in a situation where it is not desirable to derive the aspect information. ..

Features K6. The gaming machine according to feature K5, wherein the restricted situation can occur as a situation from when supply of operating power to the history storage execution means is started to when a restriction release event occurs.

According to the characteristic K6, it becomes possible to prevent the aspect information using the history information based on the occurrence of the predetermined event by the operation check immediately after the start of the supply of the operating power from being derived.

Features K7. It is characterized in that the restriction situation can occur as a situation from when the supply of the operating power to the history storage executing means is started to when the number of discharged game balls from the game area becomes a predetermined reference number or more. The gaming machine described in K5 or K6.

According to the characteristic K7, it is possible to prevent the aspect information from being derived until the number of discharged game balls from the game area reaches or exceeds the predetermined reference number after the supply of the operating power is started.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features K1 to K7. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the inventions related to the characteristic G group, the characteristic H group, the characteristic I group, the characteristic J group, and the characteristic K group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, in a pachinko machine, the game machine front face section is provided with a dish storage section for storing the game balls given to the player, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, it is necessary to manage the gaming machine appropriately, and there is still room for improvement in this respect.

<Feature L group>
Feature L1. A control unit (main CPU 63) for executing various processes and temporarily storing information in an internal storage unit (register of the main CPU 63) when the processes are executed,
The control means is
A first predetermined process executing means (a function of executing a process other than the management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing a first predetermined process among the various processes;
A second predetermined process executing means (a function of executing a management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing a second predetermined process among the various processes;
At least one stored in the internal storage means when the second predetermined process is executed from the state in which the first predetermined process is executed or when the second predetermined process is executed. A sixteenth function for executing the processing of step S3802 and steps S3902 to S3907 in the main CPU 63 in the fifteenth embodiment, which saves predetermined information, which is information on a set, to a predetermined storage means (main RAM 65) Of the main CPU 63 in the seventh embodiment, a function of executing the processes of steps S4502 to S4507 in the main CPU 63 in the seventeenth embodiment, and a step of main CPU63 in the eighteenth embodiment. A function of executing the processing of S4602, a function of executing the processing of steps S4701 and S4703 in the main CPU 63 in the nineteenth embodiment),
When or after ending the second predetermined process, a return executing unit for returning the predetermined information saved in the predetermined storage unit to the internal storage unit (in the fifteenth embodiment, step S3804 in the main CPU 63 and A function of executing the processing of steps S3910 to S3915, a function of executing the processing of step S4404 in the main CPU 63 in the sixteenth embodiment, and a processing of steps S4510 to S4515 in the main CPU 63 in the seventeenth embodiment. Function, the function of executing the process of step S4605 in the main CPU 63 in the eighteenth embodiment, and the function of executing the processes of step S4705 and step S4706 in the main CPU63 in the nineteenth embodiment).
A gaming machine characterized by being equipped with.

According to the feature L1, when the first predetermined process is being executed, the second predetermined process is being executed, or the second predetermined process is being executed, the result is stored in the internal storage means. At least a part of the information is saved in the predetermined storage means. Accordingly, when the second predetermined process is executed, it is possible to prevent the information stored in the internal storage means from being rewritten when the first predetermined process is executed. Further, when the second predetermined process is ended or after the end, the information saved in the predetermined storage means is restored to the internal storage means. As a result, when the second predetermined process is completed, it is possible to execute a process different from the second predetermined process from the state of the internal storage means before the execution of the second predetermined process. As described above, various controls can be suitably performed.

Feature L2. The gaming machine according to feature L1, wherein the predetermined information is a part of information stored in the internal storage means.

According to the feature L2, since only a part of the information stored in the internal storage means is saved in the predetermined storage means, the storage capacity necessary for saving the information in the internal storage means in the predetermined storage means is reduced. It becomes possible to suppress.

Feature L3. The internal storage means includes a first storage area (WA register, BC register, DE register, HL register, IX register, and IY register) and a second storage area (WA register, BC register, DE register, HL register, IX register, and And a register other than the IY register),
The second predetermined processing execution means is configured to store information in the first storage area in the second predetermined processing but not store information in the second storage area,
The game machine according to feature L2, wherein the save executing means saves the information stored in the first storage area to the predetermined storage means.

According to the feature L3, when the situation in which the second predetermined process is executed is changed from the situation in which the first predetermined process is executed, or when the second predetermined process is executed, the second predetermined process is performed in the internal storage means. At, the information in the first storage area, which is the storage target of the information, is saved in the predetermined storage means. As a result, when the second predetermined process is completed, it is possible to execute a process different from the second predetermined process from the state of the internal storage unit before the execution of the second predetermined process, while the internal process is performed in the predetermined storage unit. It is possible to reduce the storage capacity required to save the information in the storage means.

Feature L4. The predetermined storage means,
A first predetermined storage area (a work area 221 for specific control, a stack area 222 for specific control) in which information is stored when the first predetermined processing is executed;
A second predetermined storage area (a work area 223 for non-specific control, a stack area 224 for non-specific control) in which information is stored when the second predetermined processing is executed;
Equipped with
The game machine according to any one of features L1 to L3, wherein the save executing means saves the predetermined information in the second predetermined storage area.

According to the feature L4, since the predetermined storage means is provided with the first predetermined storage area and the second predetermined storage area, the storage destination of the information in the predetermined storage means is determined by the first predetermined processing and the second predetermined processing. It is possible to make a clear difference. This makes it possible to prevent the information used in the other process from being erased when one of the first predetermined process and the second predetermined process is executed. In this case, at least a part stored in the internal storage means when the situation in which the second predetermined process is executed from the situation in which the first predetermined process is executed or the situation in which the second predetermined process is executed Information is saved in the second predetermined storage area. As a result, it becomes possible to save the information in the internal storage means immediately before the second predetermined process is started, and it is possible to save the information without using the first predetermined storage area.

Feature L5. The evacuation executing means is
In the first predetermined process, the first predetermined information, which is a part of the information stored in the internal storage unit, is changed from the state in which the first predetermined process is being performed to the state in which the second predetermined process is being performed. Means for evacuating to the first predetermined storage area (a function of executing the process of step S3802 in the main CPU 63 in the fifteenth embodiment, a function of executing the process of step S4402 in the main CPU 63 in the sixteenth embodiment); ,
The second predetermined information, which is a part of the information stored in the internal storage means, when the second predetermined processing is executed from the state in which the first predetermined processing is executed, In the second predetermined storage area (function of executing the processing of steps S3902 to S3907 in the main CPU 63 in the fifteenth embodiment, in steps S4502 to S4507 of the main CPU 63 in the seventeenth embodiment). A function of executing the processing, a function of executing the processing of step S4602 in the main CPU 63 in the eighteenth embodiment, and a function of executing the processing of steps S4702 and S4703 in the main CPU63 in the nineteenth embodiment),
The gaming machine described in the feature L4, which is provided with.

According to the feature L5, the first predetermined information which is a part of the information stored in the internal storage means is saved in the first predetermined storage area in the first predetermined processing, and the part of the information stored in the internal storage means. The second predetermined information is saved in the second predetermined storage area in the second predetermined process. As a result, it becomes possible to save at a timing suitable for each information stored in the internal storage means, and the processing for saving the information is distributed and executed by the first predetermined processing and the second predetermined processing. It becomes possible.

Feature L6. The gaming machine according to feature L5, wherein the first predetermined information is information of a flag register provided in the internal storage means.

According to the feature L6, it is possible to appropriately save the information in the flag register in the situation where the first predetermined process is being executed.

Feature L7. The second predetermined storage area is
A stack area (a stack area 224 for non-specific control) in which information can be written by a push instruction and information can be read by a pop instruction;
A work area (a work area 223 for non-specific control) in which information can be written and read by a load instruction,
Equipped with
The game machine according to any one of features L4 to L6, wherein the save execution means saves the predetermined information in one of the stack area and the work area.

According to the feature L7, when the situation in which the second predetermined process is executed is changed from the situation in which the first predetermined process is executed, or when the second predetermined process is executed, the stack area in the second predetermined storage area And at least a part of the information stored in the internal storage means is saved in one of the work areas. As a result, it becomes possible to aggregate the save destinations of information, and it is possible to simplify the processing configuration for saving and the processing configuration for restoring.

Feature L8. The game machine according to feature L7, wherein the save executing means saves the predetermined information in the work area.

According to the characteristic L8, since the save area of at least a part of the information stored in the internal storage means is the work area, it is possible to save the information without cumulatively changing the stack pointer. Become.

Feature L9. In the first predetermined storage area, information can be stored and information can be read when the first predetermined processing is executed, and information can be read when the second predetermined processing is executed. It is impossible to store information,
In the second predetermined storage area, information can be stored and information can be read when the second predetermined processing is executed, and information can be read when the first predetermined processing is executed. The gaming machine according to any one of features L4 to L8, which is characterized in that information cannot be stored.

According to the feature L9, the first predetermined storage area can be treated as a dedicated storage area for the first predetermined processing, and the second predetermined storage area can be treated as a dedicated storage area for the second predetermined processing. Becomes

Feature L10. The predetermined storage means,
A stack area (a stack area 224 for non-specific control) in which information can be written by a push instruction and information can be read by a pop instruction;
A work area (a work area 223 for non-specific control) in which information can be written and read by a load instruction,
Equipped with
The game machine according to any one of features L1 to L9, wherein the save execution means saves the predetermined information in one of the stack area and the work area.

According to the feature L10, it is possible to aggregate the save destinations of the predetermined information, and it is possible to simplify the processing configuration for saving the predetermined information and the processing configuration for restoring the predetermined information.

Feature L11. The game machine according to feature L10, wherein the save execution means saves the predetermined information in the work area.

According to the feature L11, since the save destination of the predetermined information is the work area, it is possible to save the information without cumulatively changing the stack pointer.

Feature L12. The predetermined information is a part of information stored in the internal storage means,
The evacuation executing means is configured to execute the internal storage means when the second predetermined processing is executed from the status in which the first predetermined processing is executed, or when the second predetermined processing is executed. The gaming machine according to Feature L11, further comprising a unit (a function of executing the process of step S3802 in the main CPU 63) that saves specific information that is a part of the information stored in the stack area. ..

According to the characteristic L12, the specific information is saved in the stack area in the configuration in which the predetermined information is saved in the work area. This makes it possible to disperse and save the information stored in the internal storage means in the work area and the stack area.

Feature L13. The gaming machine according to feature L12, wherein the predetermined information has a larger amount of information than the specific information.

According to the feature L13, the predetermined information having a larger amount of information than the specific information is saved in the work area, so that a large amount of information is cumulatively stored in the stack area when the information stored in the internal storage means is saved. It is possible to prevent it.

Feature L14. Information of the stack pointer provided in the internal storage means when the state in which the second predetermined process is executed is changed from the state in which the first predetermined process is executed or when the second predetermined process is executed Is a fixed information structure,
The gaming machine according to any one of features L1 to L13, wherein the information of the stack pointer provided in the internal storage means is not a target for saving by the saving executing means.

According to the feature L14, since it is not necessary to secure the capacity for saving the information of the stack pointer in the predetermined storage means, the capacity of the predetermined storage means can be suppressed. Even if the stack pointer information is not saved in this way, the situation in which the second predetermined process is executed from the situation in which the first predetermined process is executed or the situation in which the second predetermined process is executed In this case, the information of the stack pointer becomes fixed information, so that the information of the stack pointer before the second predetermined process is started can be restored without saving the information of the stack pointer as described above. It is possible.

Feature L15. A means for setting the fixed information in the stack pointer when or after ending the second predetermined processing (in the fifteenth embodiment, a function of executing the processing of step S3909 in the main CPU 63, a seventeenth embodiment). The gaming machine according to feature L14, which has a function of executing the process of step S4509 in the main CPU 63 in the embodiment, and a function of executing the process of step S4604 in the main CPU 63 in the eighteenth embodiment). ..

According to the feature L15, it is possible to return to the information of the stack pointer before or after the second predetermined process is started, or when the second predetermined process is ended.

Feature L16. When the situation in which the second predetermined processing is executed is changed from the situation in which the first predetermined processing is executed or the second predetermined processing is executed, the stack pointer is set to the second predetermined processing. Means for setting corresponding second correspondence start information (function of executing step S3901 in the main CPU 63 in the fifteenth embodiment, function of executing step S4501 in the main CPU 63 in the seventeenth embodiment, In the eighteenth embodiment, the main CPU 63 has a function of executing the process of step S4601). The gaming machine according to the feature L14 or L15.

According to the feature L16, when the second predetermined process is started, the second correspondence start information corresponding to the second predetermined process is set in the stack pointer, so that an appropriate address in the second predetermined process is set. Information can be stored in the stack area.

Feature L17. The first predetermined process includes a process for controlling the progress of the game,
The game machine according to any one of features L1 to L16, wherein the second predetermined process includes a process for managing a game history.

According to the feature L17, the process for controlling the progress of the game is executed as the first predetermined process, and the process for managing the game history is executed as the second predetermined process to control the progress of the game. It is possible to prevent the information used in the process for managing the game history from being rewritten when executing the process.

Feature L18. The predetermined storage means,
A first predetermined storage area (a work area 221 for specific control, a stack area 222 for specific control) in which information is stored when the first predetermined processing is executed;
A second predetermined storage area (a work area 223 for non-specific control, a stack area 224 for non-specific control) in which information is stored when the second predetermined processing is executed;
Equipped with
The second predetermined storage area is a history storage area (normal counter area 231 and opening/closing execution mode counter area 232) in which history information of a game corresponding to a predetermined event generated when a game is executed is stored. , The high-frequency support mode counter area 233) is provided, the gaming machine according to Feature L17.

According to the feature L18, when a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage area. As a result, it becomes possible to store and hold information for managing the number of occurrences or the frequency of occurrence of a predetermined event in the gaming machine, and it is preferable to manage the frequency of occurrence of the predetermined event by using this managed information. It becomes possible to do it. Further, since the history information is stored in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, a process for controlling the progress of the game is executed as the first predetermined process, and a process for managing the game history is executed as the second predetermined process, whereby a process for controlling the progress of the game is executed. It is possible to prevent the information stored in the history storage area from being rewritten during execution.

Feature L19. The second predetermined process execution means uses the history information stored in the history storage area to derive mode information corresponding to the result of the game in a predetermined period (step S4208 in the main CPU 63). The game machine according to feature L18, which is provided with a function of executing the process of.

According to the feature L19, the history information stored in the history storage area is used to derive the mode information corresponding to the result of the game in the predetermined period, thereby managing the game history such as the occurrence frequency of the predetermined event. It is possible to grasp the result.

Feature L20. The gaming machine according to feature L19, wherein the second predetermined storage area includes an aspect information storage area (operation result storage area 234) that stores the aspect information derived by the information deriving means.

According to the feature L20, when the form information corresponding to the result of the game in the predetermined period is derived using the history information, the form information is stored in the form information storage area. Thereby, it becomes possible to grasp the management result of the game history at an arbitrary timing. Further, a process for controlling the progress of the game is executed as the first predetermined process, and a process for managing the game history is executed as the second predetermined process, whereby a process for controlling the progress of the game is executed. It is possible to prevent the information stored in the mode information storage area from being rewritten during execution.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features L1 to L20. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, Any one or a plurality of configurations of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature M group>
Features M1. A control unit (main CPU 63) for executing various processes and temporarily storing information in an internal storage unit (register of the main CPU 63) when the processes are executed,
The control means is
A first predetermined process executing means (a function of executing a process other than the management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing a first predetermined process among the various processes;
A second predetermined process executing means (a function of executing a management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing a second predetermined process among the various processes;
At least one stored in the internal storage means when the second predetermined process is performed from the state in which the first predetermined process is being performed, or when the second predetermined process is performed. Evacuation executing means for evacuating predetermined information, which is information of a set, to a predetermined storage means (main RAM 65) (function of executing steps S3902 to S3907 in the main CPU 63 in the fifteenth embodiment, seventeenth embodiment) Then, a function of the main CPU 63 to execute the processing of steps S4502 to S4507, a function of the main CPU 63 to execute the processing of step S4602 in the eighteenth embodiment, and a step S4701 and a step of the main CPU63 in the nineteenth embodiment. Function for executing the processing of S4703),
When or after ending the second predetermined process, a return execution unit that restores the predetermined information saved in the predetermined storage unit to the internal storage unit (step S3910 in the main CPU 63 in the fifteenth embodiment). A function of executing the process of step S3915, a function of executing the processes of steps S4510 to S4515 in the main CPU 63 in the seventeenth embodiment, a function of executing the process of step S4605 in the main CPU 63 in the eighteenth embodiment, In the nineteenth embodiment, a function of executing the processes of steps S4705 and S4706 in the main CPU 63),
Equipped with
A game machine characterized in that the save execution means saves the predetermined information in the predetermined storage means by a load command.

According to the feature M1, when the first predetermined process is executed, the second predetermined process is executed, or the second predetermined process is executed, the result is stored in the internal storage means. The predetermined information, which is at least a part of the information, is saved in the predetermined storage means. Accordingly, when the second predetermined process is executed, it is possible to prevent the information stored in the internal storage means from being rewritten when the first predetermined process is executed. Further, when or after the second predetermined process is ended, the predetermined information saved in the predetermined storage means is restored to the internal storage means. As a result, when the second predetermined process is completed, it is possible to execute a process different from the second predetermined process from the state of the internal storage means before the execution of the second predetermined process. When the situation in which the first predetermined process is being executed is changed to the situation in which the second predetermined process is executed or the second predetermined process is executed, the predetermined information is saved in the predetermined storage means by the load instruction. .. This makes it possible to save the predetermined information without changing the stack pointer.

Features M2. The predetermined storage means,
A stack area (a stack area 224 for non-specific control) in which information can be written by a push instruction and information can be read by a pop instruction;
A work area (a work area 223 for non-specific control) in which information can be written and read by a load instruction,
Equipped with
The game machine according to feature M1, wherein the save execution means saves the predetermined information in the work area.

According to the feature M2, since the save destination of the predetermined information which is at least a part of the information stored in the internal storage means is the work area, the information is saved without cumulatively changing the stack pointer. It becomes possible.

Features M3. The predetermined information is a part of information stored in the internal storage means,
The evacuation executing means is configured to perform the internal storage means when the second predetermined processing is executed from the situation in which the first predetermined processing is executed, or when the second predetermined processing is executed. The game machine according to feature M2, further comprising: a unit (a function of executing the process of step S3802 in the main CPU 63) that saves specific information that is a part of the information stored in the stack area. ..

According to the feature M3, in the configuration in which the predetermined information is saved in the work area, the specific information is saved in the stack area. This makes it possible to disperse and save the information stored in the internal storage means in the work area and the stack area.

Features M4. The gaming machine according to feature M3, wherein the predetermined information has a larger amount of information than the specific information.

According to the feature M4, the predetermined information having a larger amount of information than the specific information is saved in the work area, so that a large amount of information is cumulatively stored in the stack area when the information stored in the internal storage means is saved. It is possible to prevent it.

Features M5. The work area is
A first work area (a work area 221 for specific control) in which information is stored when the first predetermined process is executed;
A second work area (work area 223 for non-specific control) in which information is stored when the second predetermined process is executed;
Equipped with
The game machine according to any one of the features M2 to M4, wherein the save execution means saves the predetermined information in the second work area.

According to the feature M5, since the first work area and the second work area are provided in the work area, the storage destination of information in the work area is clearly different between the first predetermined process and the second predetermined process. It becomes possible. This makes it possible to prevent the information used in the other process from being erased when one of the first predetermined process and the second predetermined process is executed. In this case, at least a part stored in the internal storage means when the situation in which the second predetermined process is executed from the situation in which the first predetermined process is executed or the situation in which the second predetermined process is executed Information is saved in the second work area. This makes it possible to save the information in the internal storage unit immediately before the second predetermined process is started, and save the information without using the first work area.

Features M6. In the first work area, information can be stored and information can be read when the first predetermined process is executed, and information can be read when the second predetermined process is executed. It is impossible to store information,
In the second work area, information can be stored and information can be read when the second predetermined process is executed, and information can be read when the first predetermined process is executed. The game machine according to feature M5, which is characterized in that information cannot be stored.

According to the feature M6, the first work area can be treated as a dedicated storage area for the first predetermined processing, and the second work area can be treated as a dedicated storage area for the second predetermined processing. ..

Features M7. A control unit (main CPU 63) for executing various processes and temporarily storing information in an internal storage unit (register of the main CPU 63) when the processes are executed,
The control means is
A first predetermined process executing means (a function of executing a process other than the management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing a first predetermined process among the various processes;
A second predetermined process executing means (a function of executing a management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing a second predetermined process among the various processes;
At least one stored in the internal storage means when the second predetermined process is performed from the state in which the first predetermined process is being performed, or when the second predetermined process is performed. Evacuation executing means for evacuating predetermined information, which is information of a set, to a predetermined storage means (main RAM 65) (function of executing steps S3902 to S3907 in the main CPU 63 in the fifteenth embodiment, seventeenth embodiment) Then, a function of the main CPU 63 to execute the processing of steps S4502 to S4507, a function of the main CPU 63 to execute the processing of step S4602 in the eighteenth embodiment, and a step S4701 and a step of the main CPU63 in the nineteenth embodiment. Function for executing the processing of S4703),
When or after ending the second predetermined process, a return execution unit that restores the predetermined information saved in the predetermined storage unit to the internal storage unit (step S3910 in the main CPU 63 in the fifteenth embodiment). A function of executing the process of step S3915, a function of executing the processes of steps S4510 to S4515 in the main CPU 63 in the seventeenth embodiment, a function of executing the process of step S4605 in the main CPU 63 in the eighteenth embodiment, In the nineteenth embodiment, a function of executing the processes of steps S4705 and S4706 in the main CPU 63),
Equipped with
The predetermined storage means,
A stack area (a stack area 224 for non-specific control) in which information can be written by a push instruction and information can be read by a pop instruction;
A work area (a work area 223 for non-specific control) in which information can be written and read by a load instruction,
Equipped with
The game machine, wherein the save executing means saves the predetermined information in one of the stack area and the work area.

According to the feature M7, when the situation in which the second predetermined process is executed is changed from the situation in which the first predetermined process is executed or the situation in which the second predetermined process is executed is stored in the internal storage means. The predetermined information, which is at least a part of the information, is saved in the predetermined storage means. Accordingly, when the second predetermined process is executed, it is possible to prevent the information stored in the internal storage means from being rewritten when the first predetermined process is executed. Further, when or after the second predetermined process is ended, the predetermined information saved in the predetermined storage means is restored to the internal storage means. As a result, when the second predetermined process is completed, it is possible to execute a process different from the second predetermined process from the state of the internal storage means before the execution of the second predetermined process.

Further, when the second predetermined process is executed or the second predetermined process is executed from the state in which the first predetermined process is executed, one of the stack area and the work area in the predetermined storage unit is set. Then, the predetermined information is saved. As a result, it becomes possible to aggregate the save destinations of information, and it is possible to simplify the processing configuration for saving and the processing configuration for restoring.

In addition, with respect to the configuration of the features M1 to M7, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature N group>
Features N1. A control unit (main CPU 63) for executing various processes and temporarily storing information in an internal storage unit (register of the main CPU 63) when the processes are executed,
The control means is
A first predetermined process executing means (a function of executing a process other than the management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing a first predetermined process among the various processes;
A second predetermined process executing means (a function of executing a management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing a second predetermined process among the various processes;
Equipped with
In a case where the situation in which the second predetermined processing is executed is changed from the situation in which the first predetermined processing is executed, the information of the stack pointer provided in the internal storage means is a fixed information. A gaming machine to do.

According to the feature N1, when the second predetermined process is executed from the state in which the first predetermined process is executed, the information of the stack pointer provided in the internal storage means becomes fixed information. It is not necessary to save the information of the stack pointer when starting the predetermined process. This eliminates the need to secure a storage area for saving the stack pointer information. In addition, when the first predetermined process is being executed and the second predetermined process is being executed, the stack pointer information is fixed, so that the stack pointer information is not saved as described above. However, the information of the stack pointer before the second predetermined process is started can be restored.

Features N2. A means for setting the fixed information in the stack pointer when or after ending the second predetermined processing (in the fifteenth embodiment, a function of executing the processing of step S3909 in the main CPU 63, a seventeenth embodiment). The game machine according to the feature N1 is characterized in that it has a function of executing the process of step S4509 in the main CPU 63 in the embodiment, and a function of executing the process of step S4604 in the main CPU 63 in the eighteenth embodiment). ..

According to the feature N2, it is possible to return to the information of the stack pointer before or after the second predetermined process is started when or after the second predetermined process is ended.

Features N3. Means for setting second correspondence start information corresponding to the second predetermined process to the stack pointer when the second predetermined process is executed from the state in which the first predetermined process is being executed (fifteenth) In the seventh embodiment, the function of executing the process of step S3901 in the main CPU 63, the function of executing the process of step S4501 in the main CPU 63 in the seventeenth embodiment, and the process of step S4601 in the main CPU63 in the eighteenth embodiment. The game machine according to the feature N1 or N2.

According to the feature N3, when the second predetermined process is started, the second correspondence start information corresponding to the second predetermined process is set in the stack pointer, so that an appropriate address in the second predetermined process is set. Information can be stored in the stack area.

Features N4. At least one stored in the internal storage means when the second predetermined process is executed from the state in which the first predetermined process is executed or when the second predetermined process is executed. A sixteenth function for executing the processing of step S3802 and steps S3902 to S3907 in the main CPU 63 in the fifteenth embodiment, which saves predetermined information, which is information on a set, to a predetermined storage means (main RAM 65) Of the main CPU 63 in the seventh embodiment, a function of executing the processes of steps S4502 to S4507 in the main CPU 63 in the seventeenth embodiment, and a step of main CPU63 in the eighteenth embodiment. A function of executing the processing of S4602, a function of executing the processing of steps S4701 and S4703 in the main CPU 63 in the nineteenth embodiment),
When or after ending the second predetermined process, a return executing unit for returning the predetermined information saved in the predetermined storage unit to the internal storage unit (in the fifteenth embodiment, step S3804 in the main CPU 63 and A function of executing the processing of steps S3910 to S3915, a function of executing the processing of step S4404 in the main CPU 63 in the sixteenth embodiment, and a processing of steps S4510 to S4515 in the main CPU 63 in the seventeenth embodiment. Function, the function of executing the process of step S4605 in the main CPU 63 in the eighteenth embodiment, and the function of executing the processes of step S4705 and step S4706 in the main CPU63 in the nineteenth embodiment).
Equipped with
The gaming machine according to any one of features N1 to N3, wherein the information of the stack pointer provided in the internal storage means is not a target for saving by the saving executing means.

According to the characteristic N4, when the first predetermined process is executed, the second predetermined process is executed, or the second predetermined process is executed, the data is stored in the internal storage means. At least a part of the information is saved in the predetermined storage means. Accordingly, when the second predetermined process is executed, it is possible to prevent the information stored in the internal storage means from being rewritten when the first predetermined process is executed. Further, when the second predetermined process is ended or after the end, the information saved in the predetermined storage means is restored to the internal storage means. As a result, when the second predetermined process is completed, it is possible to execute a process different from the second predetermined process from the state of the internal storage means before the execution of the second predetermined process. Further, since the stack pointer information is not saved, it is not necessary to secure the capacity for saving the stack pointer information in the predetermined storage means. Therefore, it is possible to reduce the capacity of the predetermined storage means. Even if the stack pointer information is not saved in this way, the situation in which the second predetermined process is executed from the situation in which the first predetermined process is executed or the situation in which the second predetermined process is executed In this case, the information of the stack pointer becomes fixed information, so that the information of the stack pointer before the second predetermined process is started can be restored without saving the information of the stack pointer as described above. It is possible.

Features N5. The predetermined storage means,
A first predetermined storage area (a work area 221 for specific control, a stack area 222 for specific control) in which information is stored when the first predetermined processing is executed;
A second predetermined storage area (a work area 223 for non-specific control, a stack area 224 for non-specific control) in which information is stored when the second predetermined processing is executed;
Equipped with
The game machine according to feature N4, wherein the save executing means saves the predetermined information in the second predetermined storage area.

According to the characteristic N5, since the predetermined storage means is provided with the first predetermined storage area and the second predetermined storage area, the storage destination of the information in the predetermined storage means is determined by the first predetermined processing and the second predetermined processing. It is possible to make a clear difference. This makes it possible to prevent the information used in the other process from being erased when one of the first predetermined process and the second predetermined process is executed. In this case, at least a part stored in the internal storage means when the situation in which the second predetermined process is executed from the situation in which the first predetermined process is executed or the situation in which the second predetermined process is executed Information is saved in the second predetermined storage area. As a result, it becomes possible to save the information in the internal storage means immediately before the second predetermined process is started, and it is possible to save the information without using the first predetermined storage area.

Features N6. The first predetermined storage area can store information and read information when the first predetermined process is executed, and can read information when the second predetermined process is executed. It is impossible to store information on things,
The second predetermined storage area can store information and read information when the second predetermined process is executed, and can read information when the first predetermined process is executed. The gaming machine according to feature N5, wherein the information of the object cannot be stored.

According to the feature N6, the first predetermined storage area can be treated as a dedicated storage area for the first predetermined processing, and the second predetermined storage area can be treated as a dedicated storage area for the second predetermined processing. Becomes

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features N1 to N6. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature O group>
Features O1. A control unit (main CPU 63) for executing various processes and temporarily storing information in an internal storage unit (register of the main CPU 63) when the processes are executed,
The control means is
A first predetermined process executing means (a function of executing a process other than the management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing a first predetermined process among the various processes;
A second predetermined process executing means (a function of executing a management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing a second predetermined process among the various processes;
At least a part of the storage in the internal storage means when the second predetermined process is executed from the state in which the first predetermined process is executed or when the second predetermined process is executed First state setting means (main CPU 63 performs steps S4803 to S4808) for setting the state of a predetermined storage area (WA register, BC register, DE register, HL register, IX register, and IY register), which is an area, to a predetermined state. Function to execute)
A second state setting means (a function of executing the processes of steps S4903 to S4908 in the main CPU 63) for setting the state of the predetermined storage area to the predetermined state when or after the second predetermined process is finished;
A gaming machine characterized by being equipped with.

According to the feature O1, in the case where the second predetermined process is executed from the state in which the first predetermined process is executed or the second predetermined process is executed, the predetermined storage area of the internal storage means Is set to the predetermined state and the second predetermined process is ended or after the second predetermined process is ended, the state of the predetermined storage area is set to the predetermined state again. As a result, the state of the predetermined storage area can be set to the predetermined state before and after the second predetermined process. Therefore, it is possible to prevent the state of the predetermined storage area by one of the first predetermined process and the second predetermined process from affecting the other process. As described above, various controls can be suitably performed.

Feature O2. The gaming machine according to feature O1, wherein the predetermined state is a state when supply of operating power to the control means is started.

According to the characteristic O2, since the predetermined storage area is set to the predetermined state when the supply of the operating power to the control means is started, the processing configuration for setting the predetermined state can be simplified. Is possible.

Features O3. The gaming machine according to feature O1 or O2, wherein the predetermined state is a state in which the predetermined storage area is cleared to "0".

According to the characteristic O3, since the predetermined storage area is set to the state in which “0” is cleared as the predetermined state, the processing configuration for setting the predetermined state can be simplified.

Features O4. The gaming machine according to any one of features O1 to O3, wherein the predetermined storage area is a partial storage area in the internal storage means.

According to the characteristic O4, since only a part of the storage area of the internal storage means is set to the predetermined state, the processing load for setting the predetermined state can be reduced.

Features O5. The internal storage means includes at least the predetermined storage area and another storage area (registers other than WA register, BC register, DE register, HL register, IX register, and IY register),
The second predetermined processing execution means is configured to store information in the predetermined storage area in the second predetermined processing but not store information in the separate storage area,
The gaming machine according to feature O4, wherein the first state setting means and the second state setting means are configured not to change the state of the separate storage area.

According to the characteristic O5, when the situation in which the second predetermined process is executed is changed from the situation in which the first predetermined process is executed, or when the second predetermined process is executed, the second predetermined process is performed in the internal storage means. At, a predetermined storage area for storing information is set to a predetermined state. This makes it possible to prevent the state of the predetermined storage area by the first predetermined processing from affecting the second predetermined processing. Further, since the state of the separate storage area is not changed, setting the predetermined state when the second predetermined process is started does not affect the process after the second predetermined process is completed. It will be possible.

Features O6. Information of the predetermined storage area before the setting of the predetermined state by the first state setting means is information that is not used after the completion of the second predetermined process. The gaming machine according to any one of the above.

According to the feature O6, even if the predetermined storage area is set to the predetermined state when the second predetermined process is executed or when the second predetermined process is executed, the second predetermined process is terminated. It is possible to prevent the processing after the processing from being affected.

Features O7. A part stored in the internal storage means when the second predetermined process is executed from the state in which the first predetermined process is executed, or when the second predetermined process is executed. Save execution means (function of executing the process of step S4802 in the main CPU 63) for saving the predetermined information (flag register information), which is information of the above, in a predetermined storage means (main RAM 65).
When the second predetermined process is ended or after the end, the return execution unit for returning the predetermined information saved in the predetermined storage unit to the internal storage unit (function of executing the process of step S4810 in the main CPU 63) When,
The gaming machine according to any one of features O1 to O6.

According to the feature O7, when the first predetermined process is executed, the second predetermined process is executed, or the second predetermined process is executed, the result is stored in the internal storage means. The predetermined information, which is a part of the information, is saved in the predetermined storage means. As a result, when the second predetermined process is executed, the information stored in the internal storage means at the time of executing the first predetermined process and necessary for the subsequent execution of the first predetermined process is rewritten. It becomes possible not to. Further, when or after the second predetermined process is ended, the predetermined information saved in the predetermined storage means is restored to the internal storage means. As a result, when the second predetermined process is completed, it is possible to execute a process different from the second predetermined process from the state of the internal storage means before the execution of the second predetermined process.

Features O8. The first predetermined process includes a process for controlling the progress of the game,
The game machine according to any one of features O1 to O7, wherein the second predetermined process includes a process for managing a game history.

According to the feature O8, the process for controlling the progress of the game is executed as the first predetermined process, and the process for managing the game history is executed as the second predetermined process to control the progress of the game. It is possible to prevent the information used in the process for managing the game history from being rewritten when executing the process.

Features O9. The predetermined storage means,
A first predetermined storage area (a work area 221 for specific control, a stack area 222 for specific control) in which information is stored when the first predetermined processing is executed;
A second predetermined storage area (a work area 223 for non-specific control, a stack area 224 for non-specific control) in which information is stored when the second predetermined processing is executed;
Equipped with
The second predetermined storage area is a history storage area (normal counter area 231 and opening/closing execution mode counter area 232) in which history information of a game corresponding to a predetermined event generated when a game is executed is stored. And a high-frequency support mode counter area 233).

According to the feature O9, when a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage area. As a result, it becomes possible to store and hold information for managing the number of occurrences or the frequency of occurrence of a predetermined event in the gaming machine, and it is preferable to manage the frequency of occurrence of the predetermined event by using this managed information. It becomes possible to do it. Further, since the history information is stored in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, a process for controlling the progress of the game is executed as the first predetermined process, and a process for managing the game history is executed as the second predetermined process, whereby a process for controlling the progress of the game is executed. It is possible to prevent the information stored in the history storage area from being rewritten during execution.

Feature O10. The second predetermined processing execution means uses the history information stored in the history storage area to derive mode information corresponding to the result of the game in a predetermined period (step S4208 in the main CPU 63). The game machine according to feature O9, which is provided with a function of executing the processing of.

According to the characteristic O10, by using the history information stored in the history storage area, the form information corresponding to the result of the game in the predetermined period is derived, so that the management of the game history such as the occurrence frequency of the predetermined event is performed. It is possible to grasp the result.

Feature O11. The gaming machine according to feature O10, wherein the second predetermined storage area includes a mode information storage area (a calculation result storage area 234) that stores the mode information derived by the information deriving means.

According to the feature O11, when the form information corresponding to the result of the game in the predetermined period is derived using the history information, the form information is stored in the form information storage area. Thereby, it becomes possible to grasp the management result of the game history at an arbitrary timing. Further, a process for controlling the progress of the game is executed as the first predetermined process, and a process for managing the game history is executed as the second predetermined process, whereby a process for controlling the progress of the game is executed. It is possible to prevent the information stored in the mode information storage area from being rewritten during execution.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features O1 to O11. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, Any one or a plurality of configurations of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature P group>
Feature P1. A control unit (main CPU 63) for executing various processes and temporarily storing information in an internal storage unit (register of the main CPU 63) when the processes are executed,
The control means is
A first predetermined process executing means (a function of executing a process other than the management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing a first predetermined process among the various processes;
A second predetermined process executing means (a function of executing a management execution process in the main CPU 63 in the fifteenth to twenty-first embodiments) for executing a second predetermined process among the various processes;
A first predetermined storage area (a work area 221 for specific control, a stack area 222 for specific control) in which information is stored when the first predetermined processing is executed;
A second predetermined storage area (a work area 223 for non-specific control, a stack area 224 for non-specific control) in which information is stored when the second predetermined processing is executed;
A gaming machine characterized by being equipped with.

According to the feature P1, the first predetermined storage area and the second predetermined storage area are provided, the first predetermined storage area is treated as a storage area dedicated to the first predetermined processing, and the second predetermined storage area is It is treated as a dedicated storage area for the second predetermined process. As a result, it becomes possible to clearly make the storage destination of the information in the predetermined storage means different between the first predetermined processing and the second predetermined processing. Therefore, when one of the first predetermined process and the second predetermined process is executed, it is possible to prevent the information used in the other process from being erased.

Feature P2. The first predetermined process includes a process for controlling the progress of the game,
The game machine according to feature P1, wherein the second predetermined process includes a process for managing a game history.

According to the feature P2, the process for controlling the progress of the game is executed as the first predetermined process, and the process for managing the game history is executed as the second predetermined process to control the progress of the game. It is possible to prevent the information used in the process for managing the game history from being rewritten when executing the process.

Feature P3. The second predetermined storage area is a history storage area (normal counter area 231 and opening/closing execution mode counter area 232) in which, when a predetermined event occurs due to execution of a game, history information of the game corresponding thereto is stored. , The high-frequency support mode counter area 233) is provided, the gaming machine according to the feature P2.

According to the feature P3, when a predetermined event occurs, the history information corresponding to the predetermined event is stored in the history storage area. As a result, it becomes possible to store and hold information for managing the number of occurrences or the frequency of occurrence of a predetermined event in the gaming machine, and it is preferable to manage the frequency of occurrence of the predetermined event by using this managed information. It becomes possible to do it. Further, since the history information is stored in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, a process for controlling the progress of the game is executed as the first predetermined process, and a process for managing the game history is executed as the second predetermined process, whereby a process for controlling the progress of the game is executed. It is possible to prevent the information stored in the history storage area from being rewritten during execution.

Feature P4. The second predetermined processing execution means uses the history information stored in the history storage area to derive mode information corresponding to the result of the game in a predetermined period (step S4208 in the main CPU 63). (A function of executing the process of). The gaming machine according to feature P3.

According to the feature P4, the history information stored in the history storage area is used to derive the mode information corresponding to the result of the game in the predetermined period, thereby managing the game history such as the occurrence frequency of the predetermined event. It is possible to grasp the result.

Feature P5. The gaming machine according to feature P4, wherein the second predetermined storage area includes a mode information storage area (calculation result storage area 234) that stores the mode information derived by the information deriving means.

According to the feature P5, when the form information corresponding to the result of the game in the predetermined period is derived using the history information, the form information is stored in the form information storage area. Thereby, it becomes possible to grasp the management result of the game history at an arbitrary timing. Further, a process for controlling the progress of the game is executed as the first predetermined process, and a process for managing the game history is executed as the second predetermined process, whereby a process for controlling the progress of the game is executed. It is possible to prevent the information stored in the mode information storage area from being rewritten during execution.

Feature P6. In the first predetermined process, the first predetermined information, which is a part of the information stored in the internal storage unit, is changed from the state in which the first predetermined process is being performed to the state in which the second predetermined process is being performed. First saving means for saving to the first predetermined storage area (function of executing step S3802 in the main CPU 63 in the fifteenth embodiment, execution of step S4402 in the main CPU 63 in the sixteenth embodiment) Function),
The second predetermined information, which is a part of the information stored in the internal storage means, when the second predetermined processing is executed from the state in which the first predetermined processing is executed, In the 15th embodiment, a second evacuation means (in the fifteenth embodiment, a function of executing the processing of steps S3902 to S3907 in the main CPU 63, in the seventeenth embodiment, step S4502 of the main CPU 63 in (A function of executing the process of step S4507, a function of executing the process of step S4602 in the main CPU 63 in the eighteenth embodiment, and a function of executing the processes of step S4701 and step S4703 in the main CPU 63 in the nineteenth embodiment) When,
The gaming machine according to any one of the features P1 to P5, which is characterized by comprising:

According to the characteristic P6, the first predetermined information, which is a part of the information stored in the internal storage means, is saved in the first predetermined storage area in the first predetermined processing, and the part of the information stored in the internal storage means. The second predetermined information is saved in the second predetermined storage area in the second predetermined process. As a result, it becomes possible to save at a timing suitable for each information stored in the internal storage means, and the processing for saving the information is distributed and executed by the first predetermined processing and the second predetermined processing. It becomes possible.

Feature P7. When the second predetermined processing is ended or after the second predetermined processing is ended, first return execution means (in the fifteenth embodiment, a main return execution means for returning the first predetermined information saved in the first predetermined storage area to the internal storage means) The function of executing the process of step S3804 in the side CPU 63, the function of executing the process of step S4404 in the main CPU 63 in the sixteenth embodiment),
A second return execution unit (in the fifteenth embodiment, a main unit in the fifteenth embodiment) for returning the second predetermined information saved in the second predetermined storage area to the internal storage unit when or after the second predetermined process is finished. The function of executing the processing of steps S3910 to S3915 in the side CPU 63, the function of executing the processing of steps S4510 to S4515 in the main CPU 63 in the seventeenth embodiment, and the function of executing the step S4605 in the main CPU 63 in the eighteenth embodiment. A function of executing processing, a function of executing processing of steps S4705 and S4706 in the main CPU 63 in the nineteenth embodiment),
The gaming machine according to feature P6, which is characterized by comprising:

According to the characteristic P7, the first predetermined information saved in the first predetermined storage area is returned to the internal storage means when or after the second predetermined processing ends, and the first predetermined information saved in the second predetermined storage area Since the second predetermined information is returned to the internal storage means, the state of the internal storage means can be returned to the state before the second predetermined processing is started.

Feature P8. The game machine according to feature P6 or P7, wherein the first predetermined information includes information of a flag register provided in the internal storage means.

According to the characteristic P8, it becomes possible to appropriately save the information in the flag register in the situation where the first predetermined process is being executed.

Feature P9. The game machine according to any one of features P6 to P8, wherein the second predetermined information includes information of all registers of the internal storage means.

According to the characteristic P9, the information of all the registers of the internal storage means is collectively saved, so that it is not necessary to selectively save the information of the registers.

Feature P10. The second predetermined storage area is
A stack area (a stack area 224 for non-specific control) in which information is written by a push instruction and information is read by a pop instruction;
A work area (a work area 223 for non-specific control) in which information is written and read by a load instruction,
Equipped with
The game machine according to feature P9, wherein the second save execution means saves the second predetermined information in one of the stack area and the work area.

According to the characteristic P10, the information of all the registers of the internal storage means is saved in one of the stack area and the work area in the second predetermined storage area. As a result, the save destinations of the information in all the registers can be aggregated, and the process configuration for saving and the process configuration for restoring can be simplified.

Feature P11. The gaming machine according to feature P10, wherein the second save execution means saves the second predetermined information in the stack area.

According to the feature P11, it is possible to save the information of all the registers while not using the work area.

Feature P12. The game machine according to any one of features P6 to P11, wherein the second predetermined information includes information on a stack pointer of the internal storage means.

According to the feature P12, it is possible to appropriately save the information of the stack pointer in the situation where the first predetermined process is being executed.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features P1 to P12. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, Any one or a plurality of configurations of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the inventions related to the characteristic L group, the characteristic M group, the characteristic N group, the characteristic O group, and the characteristic P group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, various controls need to be suitably performed, and there is still room for improvement in this respect.

<Feature Q group>
Features Q1. A control unit (MPU 62) for executing various processes and temporarily storing information in an internal storage unit (register of the main CPU 63) when the processes are executed;
History storage means (management RAM 241) that is provided as a chip separate from the control means and that can temporarily store information;
Equipped with
The control means, when a predetermined event occurs due to the execution of the game, history storage execution means for storing history information of the game corresponding thereto in the history storage means (normal entrance management processing in the main CPU 63, A game machine having a function of executing a ball entrance management process in the opening/closing execution mode and a ball entrance management process in the high frequency support mode).

According to the feature Q1, when the predetermined event occurs, the history information corresponding to the predetermined event is stored in the history storage means. As a result, it becomes possible to store and hold information for managing the number of occurrences or the frequency of occurrence of a predetermined event in the gaming machine, and it is preferable to manage the frequency of occurrence of the predetermined event by using this managed information. It becomes possible to do it. Further, since the history information is stored in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, since the history storage means is provided as a chip separate from the control means, it is possible to increase the storage capacity for storing history information while using a general-purpose control means.

Features Q2. The gaming machine according to feature Q1, wherein the control means includes a predetermined storage means (main side RAM 65) that temporarily stores information when executing various types of processing.

According to the feature Q2, in the configuration including not only the predetermined storage means provided in the control means but also the history storage means provided as a chip different from the control means, by storing the history information in the history storage means. It becomes possible to store and hold a large amount of history information.

Features Q3. The gaming machine according to Feature Q2, wherein the control unit temporarily stores the information in the predetermined storage unit when executing the process related to the history information.

According to the feature Q3, in the configuration in which the history storage means for storing the history information is provided as a chip different from the control means, the predetermined storage means provided in the control means is provided when the process related to the history information is executed. Since the information is temporarily stored, it is possible to prevent the processing speed when performing the processing related to the history information from being extremely reduced.

Features Q4. The control means uses the history information stored in the history storage means to derive mode information corresponding to the result of the game in a predetermined period (the processing of step S4208 in the main CPU 63 is executed). The gaming machine according to any one of the features Q1 to Q3.

According to the characteristic Q4, by using the history information stored in the history storage means, the mode information corresponding to the result of the game in the predetermined period is derived, and the management of the game history such as the occurrence frequency of the predetermined event is performed. It is possible to grasp the result.

Features Q5. The gaming machine according to feature Q4, wherein the second predetermined storage area includes a mode information storage area (calculation result storage area 234) that stores the mode information derived by the information deriving means.

According to the feature Q5, when the form information corresponding to the result of the game in the predetermined period is derived using the history information, the form information is stored in the form information storage area. Thereby, it becomes possible to grasp the management result of the game history at an arbitrary timing.

In addition, with respect to the configuration of the features Q1 to Q5, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the characteristic Q group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, in a pachinko machine, the game machine front face section is provided with a dish storage section for storing the game balls given to the player, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, it is necessary to manage the gaming machine appropriately, and there is still room for improvement in this respect.

<Feature R group>
Feature R1. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (a function for executing the setting value updating process in the main CPU 63),
Change of the set value to be used based on the fact that a plurality of events including the first event and the second event occur when the supply of the operating power to the control means having the setting means is started. Situation generating means for providing a settable status in which the above can be performed (a function for executing the processing of steps S5003 to S5006 in the main CPU 63 in the twenty-second embodiment, or a step S5503 in the main CPU 63 in another embodiment). A function of executing the processing of step S5507, a function of executing the processing of steps S5703 to S5705 and step S5715 in the main CPU 63 in the twenty-third embodiment),
A gaming machine characterized by being equipped with.

According to the characteristic R1, the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage degree of the player, so that the player can use the more advantageous setting value as the usage target. Will be expected. In this case, in order to set the setting value to be used, a plurality of events including the first event and the second event occur when the supply of the operating power to the control means is started. Need to be As a result, it is possible to make it difficult to perform an act of setting the setting value to be used due to fraud.

Feature R2. Opening grasping means for grasping that the opening/closing body (front door frame 14) is in the open state (a function of executing the process of step S5005 in the main CPU 63 in the twenty-second embodiment, a step in the main CPU 63 in another form). A function of executing the process of S5505, and a function of executing the process of step S5703 in the main CPU 63 in the twenty-third embodiment).
A feature R1 characterized in that the situation occurrence means specifies that the first event has occurred based on the fact that the opening grasping means has grasped that the opening/closing body is in an opened state. Gaming machine described in.

According to the characteristic R2, the opening/closing body needs to be in the open state in order to set the setting value to be used. Thereby, when an act of illegally setting a setting value to be used is performed, it becomes possible to make the illegal act conspicuous, and as a result, it becomes possible to easily detect the illegal act. ..

Feature R3. Another opening grasping means (a function of executing the process of step S5006 in the main CPU 63 in the twenty-second embodiment, which grasps that the another opening/closing body (game machine main body 12) is in the open state, in another embodiment, the main CPU 63 The function of executing the process of step S5506 in step S5506, and the function of executing the process of step S5704 in the main CPU 63 in the twenty-third embodiment).
The situation occurrence means specifies that the second event has occurred based on the fact that the separate opening/closing body is in an open state is known by the separate opening grasping means. The gaming machine described in the feature R2.

According to the characteristic R3, in order to set the setting value to be used, it is necessary not only to open the opening/closing body but also open another opening/closing body. As a result, it becomes possible to make it difficult to perform the act of setting the setting value to be used due to fraud, and it becomes possible to make the fraudulent act conspicuous.

Feature R4. The setting means performs at least one of selection of the setting value to be used and setting of the setting value to be used based on operation of a predetermined operation means (update button 68b, reset button 68c). It is a configuration to do,
The gaming machine according to feature R2 or R3, wherein the predetermined operation means is operable by opening a separate opening/closing body.

According to the feature R4, the setting value to be used cannot be set unless the opening/closing body that is different from the separate opening/closing body that is opened to enable the operation of the predetermined operation means is opened. As a result, it becomes possible to make it difficult to perform the act of setting the setting value to be used due to fraud, and it becomes possible to make the fraudulent act conspicuous.

Feature R5. The opening and closing body defines the gaming machine front side of the gaming area where the gaming balls flow down,
The gaming machine according to any one of features R2 to R4, wherein the game area is opened to the front of the gaming machine by opening the opening/closing body.

According to the characteristic R5, in order to set the setting value to be used, it is necessary to open the game area to the front of the gaming machine by opening and closing the openable body. As a result, it becomes possible to make it difficult to perform the act of setting the setting value to be used due to fraud, and it becomes possible to make the fraudulent act conspicuous.

Feature R6. The situation generation means specifies that one of the plurality of events has occurred, based on the fact that the setting key insertion unit (setting key insertion unit 68a) performs a predetermined operation with the setting key. The gaming machine according to any one of features R1 to R5.

According to the characteristic R6, in order to set the setting value to be used, it is necessary not only to perform a predetermined operation with the setting key on the setting key insertion portion but also to generate an event other than that. is there. As a result, it is possible to make it difficult to perform an act of setting the setting value to be used due to fraud.

Feature R7. Based on the fact that a predetermined game event (operation of the firing operation device 28, entry into the through gate 35) that occurs when a game is played is generated, the situation generating means The gaming machine according to any one of the features R1 to R6, which is characterized in that one of the events is specified to occur.

According to the characteristic R7, in order to set the setting value to be used, not only is it necessary to generate a predetermined game event that occurs when a game is played, but it is different from that. It is necessary to cause the event of. As a result, it is possible to make it difficult to perform an act of setting the setting value to be used due to fraud.

Feature R8. The situation generating means is based on the fact that the game ball is detected by a ball detecting means (gate detecting sensor 49a) for detecting that the game ball has entered a predetermined ball portion provided in the game area. , The gaming machine according to any one of features R1 to R7, wherein one of the plurality of events is specified to occur.

According to the characteristic R8, in order to set the setting value to be used, it is necessary to enter the game ball into a predetermined ball entrance portion and to generate an event other than that. There is. As a result, it is possible to make it difficult to perform an act of setting the setting value to be used due to fraud.

Feature R9. A setting value notifying unit (a function for executing a setting confirmation process in the main CPU 63) for informing the setting value to be used set by the setting unit by the notifying unit;
The set value notifying means notifies the notifying means of the set value to be used, which is set by the setting means, based on the occurrence of a plurality of events including the first event and the second event. The gaming machine according to any one of the features R1 to R8, characterized in that the gaming machine is informed.

According to the feature R9, it is possible to make it difficult to fraudulently confirm the set value. In addition, since the manager of the game hall only needs to generate the first event and the second event regardless of whether the setting value to be used is set or the setting value is confirmed, the work is It becomes common, and it becomes easy to understand each work.

Feature R10. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (a function for executing the setting value updating process in the main CPU 63),
There are a plurality of events including both the predetermined operation by the setting key for the setting key insertion section (setting key insertion section 68a) and another event different from the predetermined operation by the setting key for the setting key insertion section. On the basis of the occurrence, the status generating means (in the twenty-second embodiment, the main CPU 63 in the main CPU 63 in the 22nd embodiment, the status setting means is set such that the setting value to be used can be set by the setting means. A function of executing the processing of steps S5003 to S5006, a function of executing the processing of steps S5503 to S5507 in the main CPU 63 in another embodiment, and a function of executing steps S5703 to S5705 and S5715 of the main CPU 63 in the twenty-third embodiment. Function to execute processing),
A gaming machine characterized by being equipped with.

According to the characteristic R10, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player can set the more advantageous setting value as the usage target. Will be expected. In this case, in order to set the setting value to be used, it is necessary not only to perform a predetermined operation on the setting key insertion portion with the setting key, but also to generate an event other than that. As a result, it is possible to make it difficult to perform an act of setting the setting value to be used due to fraud.

Feature R11. Opening grasping means for grasping that the opening/closing body (front door frame 14) is in the open state (a function of executing the process of step S5005 in the main CPU 63 in the twenty-second embodiment, a step in the main CPU 63 in another form). A function of executing the process of S5505, and a function of executing the process of step S5703 in the main CPU 63 in the twenty-third embodiment).
In the characteristic R10, the situation occurrence means specifies that the another event has occurred based on the fact that the opening grasping means has grasped that the opening/closing body is in an opened state. The game machine described.

According to the characteristic R11, the opening/closing body needs to be in the open state in order to set the setting value to be used. Thereby, when an act of illegally setting a setting value to be used is performed, it becomes possible to make the illegal act conspicuous, and as a result, it becomes possible to easily detect the illegal act. ..

Feature R12. Another opening grasping means (a function of executing the process of step S5006 in the main CPU 63 in the twenty-second embodiment, which grasps that the another opening/closing body (game machine main body 12) is in the open state, in another embodiment, the main CPU 63 The function of executing the process of step S5506 in step S5506, and the function of executing the process of step S5704 in the main CPU 63 in the twenty-third embodiment).
The status generating means identifies that one of the plurality of events has occurred based on the fact that the separate opening/closing body is in an open state and is grasped by the separate opening grasping means. The gaming machine described in the feature R11.

According to the characteristic R12, in order to set the setting value to be used, it is necessary not only to open the opening/closing body but also to open another opening/closing body. As a result, it becomes possible to make it difficult to perform the act of setting the setting value to be used due to fraud, and it becomes possible to make the fraudulent act conspicuous.

Feature R13. The setting means performs at least one of selection of the setting value to be used and setting of the setting value to be used based on operation of a predetermined operation means (update button 68b, reset button 68c). It is a configuration to do,
13. The gaming machine according to feature R11 or R12, wherein the predetermined operation means is operable by opening a separate opening/closing body.

According to the feature R13, the setting value to be used cannot be set unless the opening/closing body that is different from the separate opening/closing body that is opened so that the predetermined operation means can be operated. As a result, it becomes possible to make it difficult to perform the act of setting the setting value to be used due to fraud, and it becomes possible to make the fraudulent act conspicuous.

Feature R14. The opening and closing body defines the gaming machine front side of the gaming area where the gaming balls flow down,
The gaming machine according to any one of features R11 to R13, wherein the game area is opened to the front of the gaming machine by opening the opening/closing body.

According to the characteristic R14, in order to set the setting value to be used, it is necessary to open the game area to the front of the gaming machine by opening and closing the openable body. As a result, it becomes possible to make it difficult to perform the act of setting the setting value to be used due to fraud, and it becomes possible to make the fraudulent act conspicuous.

Feature R15. Based on the fact that a predetermined game event (operation of the firing operation device 28, entry into the through gate 35) that occurs when a game is played is generated, the situation generating means The gaming machine according to any one of features R10 to R14, which is characterized in that one of the events is specified to occur.

According to the characteristic R15, in order to set the setting value to be used, not only the predetermined operation by the setting key to the setting key insertion portion is performed, but also the predetermined value generated when the game is performed. It is necessary to generate the game event. As a result, it is possible to make it difficult to perform an act of setting the setting value to be used due to fraud.

Feature R16. The situation generating means is based on the fact that the game ball is detected by a ball detecting means (gate detecting sensor 49a) for detecting that the game ball has entered a predetermined ball portion provided in the game area. , The gaming machine according to any one of features R10 to R15, wherein one of the plurality of events is specified to occur.

According to the feature R16, in order to set the setting value to be used, not only the predetermined operation by the setting key to the setting key insertion portion is performed, but also the game ball is inserted into the predetermined ball insertion portion. You need to make a ball. As a result, it is possible to make it difficult to perform an act of setting the setting value to be used due to fraud.

Feature R17. A setting value notifying unit (a function for executing a setting confirmation process in the main CPU 63) for informing the setting value to be used set by the setting unit by the notifying unit;
The set value notifying means is based on the fact that the predetermined operation is being performed on the setting key insertion section by the setting key and that a plurality of events including both of the different events have occurred. The gaming machine according to any one of features R10 to R16, characterized in that the notification means notifies the setting value set by the above which is to be used.

According to the characteristic R17, it is possible to make it difficult to perform the act of confirming the set value by fraud. In addition, the administrator of the game hall performs a predetermined operation with the setting key on the setting key insertion part and causes another event whether the setting value to be used is set or the setting value is confirmed. Since it is sufficient to do the work, the work is shared and it becomes easy to grasp each work.

In addition, with respect to the configurations of the features R1 to R17, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, Any one or a plurality of configurations of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the characteristic R group, it is possible to solve the following problems.

Pachinko machines and slot machines are known as game machines. For example, in a pachinko machine, the game machine front face section is provided with a dish storage section for storing the game balls given to the player, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, it is necessary to deal illegally with the gaming machine, and there is still room for improvement in this respect.

<Feature S group>
Features S1. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (a function for executing the setting value updating process in the main CPU 63),
Situation generating means for setting a settable state in which the setting value to be used can be changed (in the twenty-second embodiment, processing of steps S5003 to S5006 and steps S5401 to S5408 in the main CPU 63). A function of executing the processing of steps S5503 to S5507 in the main CPU 63 in another embodiment, a function of executing the processing of steps S5703 to S5705 and S5715 in the main CPU 63 in the 23rd embodiment, In the twenty-fourth embodiment, the function of executing the processes of steps S5801 to S5804 in the main CPU63, and in the twenty-fifth embodiment of the main CPU63, a function of executing the processes of steps S5901 to S5904).
A set value grasping unit that grasps whether or not the set value before the settable state and the set value set by the setting unit are the same (step S5017 in the main CPU 63 in the twenty-second embodiment). And a function of executing the processing of steps S5111-S5112, in another embodiment, a function of executing the processing of steps S5611-S5612 in the main CPU 63).
A gaming machine characterized by being equipped with.

According to the feature S1, the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, so that the player can use the more advantageous setting value as the usage target. Will be expected. In this case, it is grasped whether or not the set value before the settable state and the set value set in the settable state are the same. This makes it possible to execute a process corresponding to whether or not the set values are the same across the settable status. Therefore, when the setting value to be used is set, it is possible to generate a favorable situation for the setting result, and it is possible to suitably perform the setting work of the setting value.

Features S2. Based on the fact that the setting value grasping unit has grasped that the setting value before the setting possible state is the same as the setting value set by the setting unit, the same-time processing corresponding thereto is performed. The same-time means to be executed (function of executing step S5113 of the main CPU 63 in the twenty-second embodiment, function of executing step S5613 of the main CPU 63 in another embodiment) is provided. The gaming machine according to feature S1.

According to the feature S2, when the set values are the same across the settable situations, the same-time processing is executed, so that it is possible to cause a preferable situation with respect to the identical set values. Become.

Features S3. The game machine according to feature S2, wherein the same time means performs a process for performing a notification corresponding to the fact that the set value is not changed, as the same time process.

According to the feature S3, it is possible to notify the manager of the game hall that the set values are the same across the settable situations.

Features S4. Based on the fact that the setting value grasping means has determined that the setting value set by the setting means is different from the setting value before the setting possible state, the corresponding non-identical processing is executed. And a non-identical means (function of executing step S5114 of the main CPU 63 in the twenty-second embodiment, function of executing step S5614 of the main CPU 63 in another embodiment). The gaming machine according to any one of the features S1 to S3.

According to the feature S4, when the set values are not the same across the settable situations, the non-identical time process is executed, so that it is possible to generate a favorable situation with respect to the changed set values. Becomes

Features S5. The non-identical time means, as the non-identical time process, executes a process for performing a notification corresponding to the change of the set value, the gaming machine according to feature S4 ..

According to the feature S5, it becomes possible to notify the manager of the game hall or the like that the set value has been changed with the settable status interposed.

Features S6. The situation generating means sets the setting based on the necessity of erasing the information in the storage means for storing the setting value after the supply of the operating power to the control means having the setting means is started. The gaming machine according to any one of the features S1 to S5, characterized in that the gaming machine is set in a possible state.

According to the feature S6, when it becomes necessary to delete the information in the storage means for storing the setting value, the setting is possible, so that the game is continued despite the setting value information being deleted. It becomes possible not to. In this case, the configuration of the feature S1 is provided, and it is grasped whether or not the set value before the settable situation and the set value set in the settable situation are the same. This makes it possible to execute a process corresponding to whether or not the set values are the same across the settable status.

Features S7. The set value is not changed based on the fact that the set value grasping unit has grasped that the set value before the settable state is the same as the set value set by the setting unit. Means for performing notification corresponding to the fact (function of executing the process of step S5113 in the main CPU 63 in the twenty-second embodiment, function of executing the process of step S5613 in the main CPU 63 in another form) The gaming machine according to feature S6, which is characterized by being provided.

According to the characteristic S7, even if the setting possible situation is brought about by the deletion of the information in the storage means, the setting value is changed if the setting possible values are the same and the setting possible situation is sandwiched therebetween. The notification corresponding to the absence is made. This makes it possible to notify the player that the set value has not been changed even if the setting is possible during the game, and the player is safe even if the setting is possible during the game. It becomes possible to continue playing the game with care.

Features S8. The situation generating means,
The first situation generating means for setting the setting possible situation based on the start of the supply of the operating power to the control means having the setting means (in the twenty-second embodiment, steps S5003 to S5003 in the main CPU 63). A function of executing the process of step S5006, a function of executing the processes of steps S5503 to S5507 in the main CPU 63 in another embodiment, a process of steps S5703 to S5705 and S5715 in the main CPU 63 in the 23rd embodiment. Function),
A second situation in which the setting possible state is set based on the need to erase the information in the storage unit that stores the setting value after the supply of the operating power to the control unit is started. Generating means (a function of executing the processing of steps S5401 to S5408 in the main CPU 63 in the 22nd embodiment, a function of executing the processing of steps S5801 to S5804 in the main CPU 63 in the 24th embodiment, the 25th In the embodiment, the function of executing the processes of steps S5901 to S5904 in the main CPU 63),
Equipped with
The set value grasping means is set to the settable status regardless of whether the settable status is generated by the first status generating means or the settable status is generated by the second status generating means. The gaming machine according to any one of features S1 to S7, wherein the gaming machine according to any one of features S1 to S7 is configured to grasp whether or not the set value in step 1 is the same as the set value set by the setting means.

According to the characteristic S8, when it becomes necessary to delete the information in the storage means for storing the setting value, the setting becomes possible, so that the game is continued even though the setting value information is deleted. It becomes possible not to. In this case, using the same processing as the case where the setting possible situation is set based on the start of the supply of the operating power to the control means, the setting possible situation is accompanied by the deletion of the information in the storage means. When occurs, it is possible to execute the process corresponding to whether or not the set values are the same across the settable situation.

In addition, with respect to the configurations of the features S1 to S8, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the above characteristic S group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, in a pachinko machine, the game machine front face section is provided with a dish storage section for storing the game balls given to the player, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as exemplified above, when a setting value that determines the advantage of the gaming machine is set, it is necessary to generate a suitable situation for that, and this point is still improved. There is room for

<Feature T group>
Feature T1. A control unit (main CPU 63) for executing various processes and temporarily storing information in an internal storage unit (register of the main CPU 63) when the processes are executed,
The control means is
A first predetermined process execution means (a function of executing a process other than the management execution process in the main CPU 63 in the fifteenth to twenty-fifth embodiments) for executing a first predetermined process among the various processes;
A second predetermined process executing means (a function of executing a management execution process in the main CPU 63 in the fifteenth to twenty-fifth embodiments) for executing a second predetermined process among the various processes;
A first predetermined storage area (a work area 221 for specific control, a stack area 222 for specific control) in which information is stored when the first predetermined processing is executed;
A second predetermined storage area (a work area 223 for non-specific control, a stack area 224 for non-specific control) in which information is stored when the second predetermined processing is executed;
First monitoring execution means for monitoring whether or not the first predetermined storage area is normal (in the twenty-second embodiment, a function of executing the processing of steps S5401 to S5404 in the main CPU 63, in the twenty-fourth embodiment Function of executing the processing of steps S5801 to S5804 in the main CPU 63, function of executing the processing of steps S5901 to S5904 in the main CPU 63 in the twenty-fifth embodiment, step S7701 of the main CPU63 in the thirty-second embodiment. The function of executing the processing of step S7703),
Second monitoring execution means for monitoring whether or not the second predetermined storage area is normal (in the twenty-second embodiment, a function of executing the processing of steps S5405 to S5408 in the main CPU 63, in the twenty-fourth embodiment. A function of executing the processes of steps S5809, S5810, S5812, and S5813 in the main CPU 63, and a function of executing the processes of steps S6101, S6102, S6105, and S6106 in the main CPU 63 in the twenty-fifth embodiment. In the thirty-second embodiment, a function of executing the processes of steps S7706 to S7708 in the main CPU 63),
A gaming machine characterized by being equipped with.

According to the feature T1, the first predetermined storage area and the second predetermined storage area are provided, the first predetermined storage area is treated as a storage area dedicated to the first predetermined processing, and the second predetermined storage area is It is treated as a dedicated storage area for the second predetermined process. As a result, it becomes possible to clearly make the storage destination of the information in the predetermined storage means different between the first predetermined processing and the second predetermined processing. Therefore, when one of the first predetermined process and the second predetermined process is executed, it is possible to prevent the information used in the other process from being erased. In addition, the first predetermined processing and the second predetermined processing are performed by monitoring whether the first predetermined storage area is normal and by monitoring whether the second predetermined storage area is normal. It is possible to specify whether or not the situation is such that each of the processes can be performed normally.

Feature T2. The game according to the feature T1, wherein the monitoring by the first monitoring execution means and the monitoring by the second monitoring execution means are executed by either one of the first predetermined processing and the second predetermined processing. Machine.

According to the feature T2, monitoring of whether the first predetermined storage area is normal and monitoring of whether the second predetermined storage area is normal are performed by one of the first predetermined processing and the second predetermined processing. It is executed collectively. As a result, it is possible to simplify the processing configuration as compared with the configuration in which the monitoring of each storage area is distributed and executed by the first predetermined processing and the second predetermined processing.

Feature T3. The gaming machine according to feature T1 or T2, wherein the monitoring by the first monitoring execution means and the monitoring by the second monitoring execution means are executed in the first predetermined processing.

According to the feature T3, it is possible to collectively monitor whether the first predetermined storage area is normal and monitor whether the second predetermined storage area is normal by the first predetermined processing. Becomes

Feature T4. A predetermined erasing unit (in the twenty-second embodiment, the main side) for erasing information in the first predetermined storage region based on the fact that the first monitoring execution unit specifies that the first predetermined storage region is abnormal. Function of executing the process of step S5410 in the CPU 63, function of executing the processes of step S5806, step S5811 and step S5814 in the main CPU 63 in the twenty-fourth embodiment, step S5906, step of the main CPU63 in the twenty-fifth embodiment The game machine according to any one of features T1 to T3, which is provided with a function of executing the processing of S6103 and step S6107.

According to the feature T4, when the first predetermined storage area is abnormal, the information in the first predetermined storage area is erased, so that the first predetermined processing is executed while the first predetermined storage area is in the abnormal state. It is possible to prevent it.

Feature T5. The predetermined erasing means erases information in the first predetermined storage area based on the fact that the first monitoring execution means identifies that the first predetermined storage area is abnormal, and the second predetermined storage area. The gaming machine according to feature T4, which is characterized by erasing information in the area.

According to the feature T5, when the first predetermined storage area is abnormal, not only the first predetermined storage area but also the second predetermined storage area is erased. As a result, when there is a possibility that an abnormality has occurred in the second predetermined storage area, it becomes possible to erase the information in the second predetermined storage area regardless of the monitoring result by the second monitoring execution means.

Feature T6. The predetermined erasing means erases the information in the second predetermined storage area based on the fact that the second monitoring execution means specifies that the second predetermined storage area is abnormal. The gaming machine described in T4 or T5.

According to the feature T6, when the first predetermined storage area is abnormal, the information in the first predetermined storage area is erased, so that the first predetermined processing is executed while the first predetermined storage area is in the abnormal state. It is possible to prevent it.

Feature T7. The predetermined erasing means erases the information in the second predetermined storage area based on the fact that the second monitoring execution means identifies that the second predetermined storage area is abnormal, and the first predetermined storage area. The gaming machine according to feature T6, characterized by erasing information in the area.

According to the characteristic T7, when the second predetermined storage area is abnormal, not only the second predetermined storage area but also the first predetermined storage area is erased. Accordingly, when there is a possibility that an abnormality has occurred in the first predetermined storage area, it becomes possible to erase the information in the first predetermined storage area regardless of the monitoring result by the first monitoring execution means.

Feature T8. The processing for erasing information by the predetermined erasing means is executed in either one of the first predetermined processing and the second predetermined processing, in any one of characteristics T4 to T7. Game machine.

According to the feature T8, the process of deleting the information in each predetermined storage area based on the fact that the abnormality is specified is collectively executed by one of the first predetermined process and the second predetermined process. As a result, it becomes possible to simplify the processing configuration as compared with the configuration in which the erasing of information in each storage area is performed in a distributed manner by the first predetermined processing and the second predetermined processing.

Feature T9. The gaming machine according to any one of features T4 to T7, wherein a process for erasing information by the predetermined erasing means is executed in the first predetermined process.

According to the feature T9, it is possible to collectively execute the processing of erasing the information in the predetermined storage areas based on the fact that the abnormality is specified, in the first predetermined processing.

Feature T10. The first predetermined process includes a process for controlling the progress of the game,
The game machine according to any one of features T1 to T9, wherein the second predetermined process includes a process for managing a game history.

According to the feature T10, the process for controlling the progress of the game is executed as the first predetermined process, and the process for managing the game history is executed as the second predetermined process to control the progress of the game. It is possible to prevent the information used in the process for managing the game history from being rewritten when executing the process.

Feature T11. The second predetermined storage area is a history storage area (normal counter area 231 and opening/closing execution mode counter area 232) in which history information of a game corresponding to a predetermined event generated when a game is executed is stored. , The high-frequency support mode counter area 233) is provided, the gaming machine according to Feature T10.

According to feature T11, when a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage area. As a result, it becomes possible to store and hold information for managing the number of occurrences or the frequency of occurrence of a predetermined event in the gaming machine, and it is preferable to manage the frequency of occurrence of the predetermined event by using this managed information. It becomes possible to do it. Further, since the history information is stored in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, a process for controlling the progress of the game is executed as the first predetermined process, and a process for managing the game history is executed as the second predetermined process, whereby a process for controlling the progress of the game is executed. It is possible to prevent the information stored in the history storage area from being rewritten during execution.

Feature T12. The second predetermined processing execution means uses the history information stored in the history storage area to derive mode information corresponding to the result of the game in a predetermined period (step S4208 in the main CPU 63). The game machine according to the feature T11, which is provided with a function of executing the process of.

According to the feature T12, by using the history information stored in the history storage area, the form information corresponding to the result of the game in the predetermined period is derived, so that the management of the game history such as the occurrence frequency of the predetermined event is performed. It is possible to grasp the result.

Feature T13. The gaming machine according to feature T12, wherein the second predetermined storage area includes a mode information storage area (a calculation result storage area 234) that stores the mode information derived by the information deriving means.

According to the feature T13, when the form information corresponding to the result of the game in the predetermined period is derived using the history information, the form information is stored in the form information storage area. Thereby, it becomes possible to grasp the management result of the game history at an arbitrary timing. Further, a process for controlling the progress of the game is executed as the first predetermined process, and a process for managing the game history is executed as the second predetermined process, whereby a process for controlling the progress of the game is executed. It is possible to prevent the information stored in the mode information storage area from being rewritten during execution.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features T1 to T13. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, Any one or a plurality of configurations of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature U group>
Features U1. A control unit (main CPU 63) for executing various processes and temporarily storing information in an internal storage unit (register of the main CPU 63) when the processes are executed,
The control means is
A first predetermined process executing means (a function of executing a process other than the management execution process in the main CPU 63 in the fifteenth to thirty-fourth embodiments) for executing a first predetermined process among the various processes;
A second predetermined process executing means (a function of executing a management execution process in the main CPU 63 in the fifteenth to thirty-fourth embodiments) for executing a second predetermined process among the various processes;
A flag register provided in the internal storage means when the second predetermined process is executed from the state in which the first predetermined process is executed or when the second predetermined process is executed State setting means for causing the state of No. to become the specific state (in the twenty-sixth embodiment, a function of executing the processing of steps S6202 to S6204 and step S6211 in the main CPU 63, in the twenty-seventh embodiment, the step in the main CPU63 A function of executing the processing of S6302 to step S6307 and step S6312),
A gaming machine characterized by being equipped with.

According to the characteristic U1, when the second predetermined process is executed or the second predetermined process is executed from the condition in which the first predetermined process is executed, the flag register of the internal storage means is changed. The state is set to a specific state. This makes it possible to start the second predetermined process in a situation where the state of the flag register is in a predetermined specific state. Therefore, various controls can be suitably performed.

Features U2. The gaming machine according to feature U1, wherein the specific state is a state when supply of operating power to the control means is started.

According to the characteristic U2, the flag register is set to the state when the supply of the operating power to the control means is started as the specific state, so that the processing configuration for setting the specific state can be simplified. It will be possible.

Features U3. The specific state is a state in which the flag register is cleared to "0". The gaming machine according to the feature U1 or U2.

According to the feature U3, the flag register is set to a state in which “0” is cleared as the specific state, so that the processing configuration for setting the specific state can be simplified.

Features U4. A means for causing the state of the flag register to be the specific state when or after the second predetermined process is finished (in the twenty-sixth embodiment, the processes of steps S6213 to S6218 in the main CPU 63 are executed). The game machine according to any one of the features U1 to U3, which has a function, in the twenty-seventh embodiment, a function of executing the processes of steps S6314 to S6322 in the main CPU 63.

According to the characteristic U4, the second predetermined process is performed not only when the second predetermined process is executed from the state where the first predetermined process is executed or when the second predetermined process is executed. The state of the flag register is set to the specific state when the process ends or when the process ends. As a result, the first predetermined process can be restarted in a situation where the state of the flag register is the predetermined specific state. Further, it becomes possible to set the state of the flag register to the specific state before and after the second predetermined process. Therefore, it is possible to prevent the state of the flag register by one of the first predetermined process and the second predetermined process from affecting the other process.

Features U5. A predetermined storage unit (main side RAM 65) for temporarily storing information when the control unit executes processing,
The state setting means,
A means for changing the state of a predetermined storage area in the predetermined storage means to the specific state (in the twenty-sixth embodiment, a function of executing steps S6202 to S6204 in the main CPU 63, in the twenty-seventh embodiment). A function of executing the processes of steps S6302 to S6307 in the main CPU 63),
A unit that stores the information stored in the predetermined storage area in the flag register so that the state of the flag register becomes the specific state (in the twenty-sixth embodiment, the processing of step S6211 in the main CPU 63 is performed). A function to execute, a function to execute the process of step S6312 in the main CPU 63 in the twenty-seventh embodiment),
The gaming machine according to any one of the features U1 to U4.

According to the characteristic U5, even if the flag register state cannot be directly set to a specific state as an instruction of the control means, the flag is written by using the writing of information to the predetermined storage means and the reading of the information. It becomes possible to set the state of the register to a specific state.

Features U6. The predetermined storage means,
A stack area (stack area 222 for specific control) in which the control unit can write information by a push command and the control unit can read information by a pop command;
A work area (a work area 221 for specific control) in which the control means can write and read information by a load instruction;
Equipped with
The gaming machine according to feature U5, wherein the predetermined storage area is provided in the stack area.

According to feature U6, even if the information stored in the work area cannot be directly written to the flag register, the state of the flag register can be specified by writing the information to the stack area and reading the information. It is possible to set the state.

Features U7. A predetermined register provided in the internal storage means when the second predetermined process is executed from the state in which the first predetermined process is executed or when the second predetermined process is executed. Means for making the state of the predetermined state the predetermined state (in the twenty-sixth embodiment, the function of executing the processing of steps S6205 to S6210 in the main CPU 63, in the twenty-seventh embodiment of the steps S6308 to S6311 of the main CPU63). Function to execute processing)
The state setting means sets the state of the flag register to the specific state after the state of the predetermined register is set to the predetermined state, according to any one of features U1 to U6. Amusement machine.

The state of the flag register may change each time the control means executes various processes. In this case, according to the characteristic U7, since the state of the flag register is set to the specific state after the state of the predetermined register is set to the predetermined state, the flag register is set to the specific state immediately before the second predetermined process is started. It becomes possible to do so.

Features U8. A control unit (main CPU 63) for executing various processes and temporarily storing information in an internal storage unit (register of the main CPU 63) when the processes are executed,
The control means is means for causing the state of the flag register to be in a specific state (in the twenty-sixth embodiment, a function of executing the processing of steps S6202 to S6204 and step S6211 in the main CPU 63, the twenty-seventh embodiment). Then, a gaming machine having a function of executing steps S6302 to S6307 and step S6312 in the main CPU 63).

According to the feature U8, it becomes possible to set the state of the flag register to a specific state if necessary.

In addition, with respect to the configurations of the features U1 to U8, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature V group>
Features V1. A control unit (main CPU 63) for executing various processes and temporarily storing information in an internal storage unit (register of the main CPU 63) when the processes are executed,
The control means is
A first predetermined process executing means (a function of executing a process other than the management execution process in the main CPU 63 in the fifteenth to thirty-fourth embodiments) for executing a first predetermined process among the various processes;
A second predetermined process executing means (a function of executing a management execution process in the main CPU 63 in the fifteenth to thirty-fourth embodiments) for executing a second predetermined process among the various processes;
A flag register provided in the internal storage means when the second predetermined process is executed from the state in which the first predetermined process is executed or when the second predetermined process is executed Information in a predetermined storage unit (main side RAM 65) for saving execution means (function of executing step S3802 in the main side CPU 63 in the fifteenth embodiment, step S4402 in main side CPU 63 in the sixteenth embodiment). A function of executing the process, a function of executing the process of step S4802 in the main CPU 63 in the twentieth embodiment, a function of executing the process of steps S6402 to S6405 in the main CPU 63 in the twenty-eighth embodiment, and a twenty-ninth embodiment. In the embodiment, the function of executing the processing of steps S6502 to S6509 in the main CPU 63),
In the case of ending the second predetermined process or after the second predetermined process, return execution means for returning the information in the flag register saved in the predetermined storage means to the flag register (in the fifteenth embodiment, step S3804 in the main CPU 63). Function of executing step S4404 of the main CPU 63 in the sixteenth embodiment, function of executing step S4810 of the main CPU 63 in the twentieth embodiment, and twenty-eighth embodiment. A function of the main CPU 63 to execute the processing of steps S6407 to S6415, and a function of the main CPU 63 to execute the processing of steps S6511 to S6518 in the twenty-ninth embodiment).
A gaming machine characterized by being equipped with.

According to the characteristic V1, the information of the flag register is stored in a predetermined manner when the second predetermined process is executed from the state in which the first predetermined process is executed, or when the second predetermined process is executed. It is evacuated to the means. This makes it possible to prevent the information stored in the flag register from being rewritten when the first predetermined process is executed when the second predetermined process is executed. In addition, the information saved in the predetermined storage means is restored to the flag register when or after the second predetermined processing is ended. As a result, when the second predetermined process is completed, it is possible to execute a process different from the second predetermined process from the state of the flag register before the execution of the second predetermined process. As described above, various controls can be suitably performed.

Features V2. The predetermined storage means,
A first predetermined storage area (a work area 221 for specific control, a stack area 222 for specific control) in which information is stored when the first predetermined processing is executed;
A second predetermined storage area (a work area 223 for non-specific control, a stack area 224 for non-specific control) in which information is stored when the second predetermined processing is executed;
Equipped with
The game machine according to feature V1, wherein the save executing means saves the information in the flag register to the first predetermined storage area.

According to the characteristic V2, since the predetermined storage means is provided with the first predetermined storage area and the second predetermined storage area, the storage destination of the information in the predetermined storage means is determined by the first predetermined processing and the second predetermined processing. It is possible to make a clear difference. This makes it possible to prevent the information used in the other process from being erased when one of the first predetermined process and the second predetermined process is executed. In this case, when the situation in which the second predetermined processing is executed is changed from the situation in which the first predetermined processing is executed, or when the second predetermined processing is executed, the information in the flag register is the first predetermined storage area. Be evacuated to. This makes it possible to save the information in the flag register immediately before the second predetermined process is started, and save the information without using the second predetermined storage area.

Features V3. In the first predetermined storage area, information can be stored and information can be read when the first predetermined processing is executed, and information can be read when the second predetermined processing is executed. It is impossible to store information,
In the second predetermined storage area, information can be stored and information can be read when the second predetermined process is executed, and information can be read when the first predetermined process is executed. The gaming machine according to feature V2, which is characterized in that information cannot be stored.

According to the feature V3, the first predetermined storage area can be treated as a dedicated storage area for the first predetermined processing, and the second predetermined storage area can be treated as a dedicated storage area for the second predetermined processing. Becomes

Features V4. The predetermined storage means,
A stack area (a stack area 222 for specific control) in which information can be written by a push instruction and information can be read by a pop instruction;
A work area (a work area 221 for specific control) in which information can be written and read by a load instruction,
Equipped with
The game machine according to any one of features V1 to V3, wherein the save execution means saves information in the flag register to one of the stack area and the work area.

According to the feature V4, when the situation in which the second predetermined process is executed is changed from the situation in which the first predetermined process is executed or when the second predetermined process is executed, the stack area in the second predetermined storage area And the information of the flag register is saved in one of the work areas. As a result, it becomes possible to aggregate the save destinations of information, and it is possible to simplify the processing configuration for saving and the processing configuration for restoring.

Features V5. The game machine according to feature V4, wherein the save executing means saves the information in the flag register to the work area.

According to the feature V5, since the save destination of the information in the flag register is the work area, it is possible to save the information without cumulatively changing the stack pointer.

Features V6. The evacuation executing means is
A means for storing the information of the flag register in a predetermined register provided in the internal storage means (a function for executing the processing of steps S6402 and S6403 in the main CPU 63 in the twenty-eighth embodiment, a main function in the twenty-ninth embodiment). Function of executing the processing of steps S6502 to S6505 in the side CPU 63),
Means for storing information of the flag register stored in the predetermined register in the predetermined storage means (function of executing step S6404 in the main CPU 63 in the 28th embodiment, main CPU 63 in the 29th embodiment). In step S6506))),
The gaming machine according to any one of the features V1 to V5, which is characterized by comprising:

According to the characteristic V6, even if the information of the flag register cannot be directly saved in the predetermined storage means as an instruction of the control means, the information is written in the predetermined register and the information stored in the predetermined register is predetermined. It is possible to save the information in the flag register to the predetermined storage means by using the writing to the storage means.

In addition, with respect to the configurations of the features V1 to V6, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature W group>
Features W1. A control means (main CPU 63) for executing various processes is provided,
The control means is
A first predetermined process executing means (a function of executing a process other than the management execution process in the main CPU 63 in the fifteenth to thirty-fourth embodiments) for executing a first predetermined process among the various processes;
A second predetermined process executing means (a function of executing a management execution process in the main CPU 63 in the fifteenth to thirty-fourth embodiments) for executing a second predetermined process among the various processes;
A first predetermined storage area (a work area 221 for specific control, a stack area 222 for specific control) in which information is stored when the first predetermined processing is executed;
A second predetermined storage area (a work area 223 for non-specific control, a stack area 224 for non-specific control) in which information is stored when the second predetermined processing is executed;
An abnormal event monitoring unit (a program monitoring unit 252) for monitoring whether or not an abnormal event has occurred,
It is possible to cause a situation in which the information erasing process is executed to at least the first predetermined storage area based on the fact that the abnormal event monitoring unit has specified that the abnormal event has occurred. Erasing status generating means (reset signal output unit 251),
A gaming machine characterized by being equipped with.

According to the feature W1, the first predetermined storage area and the second predetermined storage area are provided, the first predetermined storage area is treated as a storage area dedicated to the first predetermined processing, and the second predetermined storage area is It is treated as a dedicated storage area for the second predetermined process. As a result, it becomes possible to clearly make the storage destination of the information in the predetermined storage means different between the first predetermined processing and the second predetermined processing. Therefore, when one of the first predetermined process and the second predetermined process is executed, it is possible to prevent the information used in the other process from being erased. Further, the information erasing process is executed on at least the first predetermined storage area based on the fact that the abnormal event has been identified. This makes it possible to prevent the first predetermined process from being executed in a state where the information in the first predetermined storage area is held as it is, despite the occurrence of the abnormal event.

Features W2. The control means is
Means for executing processing for storing power failure correspondence information when supply of operating power to the control means is stopped (in the thirtieth embodiment, a function for executing the processing of steps S6709 and S6710 in the main CPU 63) In the thirty-second embodiment, the function of executing the processing of steps S7609 to S7611 in the main CPU 63),
When the supply of the operating power to the control means is started and the processing at the start of the supply is executed in a situation where the power failure correspondence information is not stored, the information erasing processing is performed on at least the first predetermined storage area. Means for executing the processing in step S6607 in the main CPU 63 in the thirtieth embodiment, a function for executing the clear processing at the time of abnormality in the main CPU63 in the thirty-first embodiment, and the thirty-second embodiment. In the above embodiment, the function of executing the processes of steps S7704, S7705, S7808, and S7810 in the main CPU 63),
Equipped with
The erasure status generation means starts the supply by the control means in a situation where the power failure correspondence information is not stored, based on the fact that the abnormal event has been identified by the abnormal event monitoring means. The gaming machine described in the feature W1 is characterized in that the process at the time is executed.

According to the characteristic W2, when the supply of the operating power to the control means is started and the process at the start of the supply is executed in the situation where the power failure correspondence information is not stored, the information erasing process is at least the first predetermined. By being executed for the storage area, the information of the first predetermined storage area is retained as it is when the supply of operating power to the control means is started in a situation where the process at the time of power failure is not properly performed. It is possible to prevent the first predetermined process from being executed in this state. In this case, on the basis of the fact that the abnormal event has been identified, the control means executes the process at the start of supply in the situation where the power failure response information is not stored. As a result, when the control means executes the process at the time of starting the supply in the situation where the power failure correspondence information is not stored, the configuration for executing the information erasing process is used, and the information of the abnormal event is generated. It becomes possible to execute the erasing process.

Features W3. The control means executes various processes when a reset signal is received, and receives the reset signal from a situation where the reset signal is not received in a situation where operating power is supplied. The process at the start of the supply is started based on the situation that
The erasing status generation means is configured to notify the control means after the control means does not receive the reset signal based on the fact that the abnormal event has been identified by the abnormal event monitoring means. The game machine according to feature W2, wherein the game machine is set to receive the reset signal.

According to the feature W3, it is possible to achieve the above-mentioned excellent effects by switching the reception state of the reset signal.

Features W4. The control unit is configured to temporarily store information in an internal storage unit (a register and a program counter of the main CPU 63) when executing a process, and the information stored in the internal storage unit is stored in the first predetermined storage unit. It is a configuration that can be temporarily saved in the area,
The abnormal event monitoring means, as the abnormal event, monitors whether or not an abnormality has occurred in the information stored in the internal storage means,
Any one of the characteristics W1 to W3 is characterized in that the erasing status generating means causes a status in which the erasing processing of the information is executed on at least both the first predetermined storage area and the internal storage means. Gaming machine described in.

According to the feature W4, the information stored in the internal storage means can be temporarily saved in the first predetermined storage area. Therefore, when an abnormality occurs in the information stored in the internal storage means, 1 There is a possibility that an abnormality has occurred in the information stored in the predetermined storage area. In this case, when an abnormality occurs in the information stored in the internal storage means, the information erasing process is executed not only in the internal storage means but also in the first predetermined storage area. As a result, it is possible to prevent the first predetermined process from being executed as it is, even if an abnormality has occurred in the information stored in the first predetermined storage area.

Features W5. The erasure status generating means prevents the erasing process of the information from being performed on the second predetermined storage area even if the abnormal event monitoring means specifies that the abnormal event has occurred. The gaming machine according to any one of features W1 to W4.

According to the feature W5, even if an abnormal event occurs, information can be stored and held in the second predetermined storage area.

Features W6. The erasure status generating means performs the information erasing process on the basis of the fact that the abnormal event has been identified by the abnormal event monitoring means as the first predetermined storage area and the second predetermined storage area. The gaming machine according to any one of the features W1 to W4, which causes a situation to be executed for both.

According to the feature W6, the information erasing process is executed for both the first predetermined storage area and the second predetermined storage area based on the fact that the abnormal event has been identified. This makes it possible to prevent the first predetermined process from being executed in a state where the information in the first predetermined storage area is retained as it is even though an abnormal event has occurred, and an abnormal event has occurred. Nevertheless, it is possible to prevent the second predetermined process from being executed in a state where the information in the second predetermined storage area is retained as it is.

Features W7. The erasing process of the information in the first predetermined storage area is performed in the first predetermined process, and the erasing process of the information in the second predetermined storage region is performed in the second predetermined process. The gaming machine according to W6.

According to the feature W7, also in the information erasing process, the first predetermined storage area is treated as a dedicated storage area for the first predetermined processing, and the second predetermined storage area is treated as a dedicated storage area for the second predetermined processing. It becomes possible to be exposed.

Features W8. The first predetermined process includes a process for controlling the progress of the game,
The game machine according to any one of features W1 to W7, wherein the second predetermined process includes a process for managing a game history.

According to the feature W8, the process for controlling the progress of the game is executed as the first predetermined process, and the process for managing the game history is executed as the second predetermined process, thereby controlling the progress of the game. It is possible to prevent the information used in the process for managing the game history from being rewritten when executing the process.

Features W9. The second predetermined storage area is a history storage area (normal counter area 231 and opening/closing execution mode counter area 232) in which, when a predetermined event occurs due to execution of a game, history information of the game corresponding thereto is stored. , The high-frequency support mode counter area 233) is provided, the gaming machine according to Feature W8.

According to the feature W9, when a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage area. As a result, it becomes possible to store and hold information for managing the number of occurrences or the frequency of occurrence of a predetermined event in the gaming machine, and it is preferable to manage the frequency of occurrence of the predetermined event by using this managed information. It becomes possible to do it. Further, since the history information is stored in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, a process for controlling the progress of the game is executed as the first predetermined process, and a process for managing the game history is executed as the second predetermined process, whereby a process for controlling the progress of the game is executed. It is possible to prevent the information stored in the history storage area from being rewritten during execution.

Features W10. The second predetermined process execution means uses the history information stored in the history storage area to derive mode information corresponding to the result of the game in a predetermined period (step S4208 in the main CPU 63). The game machine according to the feature W9, which is provided with a function of executing the process of.

According to the feature W10, the history information stored in the history storage area is used to derive the mode information corresponding to the result of the game in the predetermined period, thereby managing the game history such as the occurrence frequency of the predetermined event. It is possible to grasp the result.

Features W11. The gaming machine according to Feature W10, wherein the second predetermined storage region includes a feature information storage region (calculation result storage area 234) that stores the feature information derived by the information deriving unit.

According to the characteristic W11, when the form information corresponding to the result of the game in the predetermined period is derived using the history information, the form information is stored in the form information storage area. Thereby, it becomes possible to grasp the management result of the game history at an arbitrary timing. Further, a process for controlling the progress of the game is executed as the first predetermined process, and a process for managing the game history is executed as the second predetermined process, whereby a process for controlling the progress of the game is executed. It is possible to prevent the information stored in the mode information storage area from being rewritten during execution.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features W1 to W11. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, Any one or a plurality of configurations of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature X group>
Feature X1. A control means (main CPU 63) for executing various processes is provided,
The control means is
A first predetermined process executing means (a function of executing a process other than the management execution process in the main CPU 63 in the fifteenth to thirty-fourth embodiments) for executing a first predetermined process among the various processes;
A second predetermined process executing means (a function of executing a management execution process in the main CPU 63 in the fifteenth to thirty-fourth embodiments) for executing a second predetermined process among the various processes;
A first predetermined storage area (a work area 221 for specific control, a stack area 222 for specific control) in which information is stored when the first predetermined processing is executed;
A second predetermined storage area (a work area 223 for non-specific control, a stack area 224 for non-specific control) in which information is stored when the second predetermined processing is executed;
Equipped with
The second predetermined processing execution means executes the deletion processing of information on the second predetermined storage area as the second predetermined processing based on the occurrence of the deletion trigger. In the twenty-fifth embodiment, the main CPU 63 performs the processing of steps S6103 and S6107, in the thirtieth embodiment, the main CPU63 performs the processing of step S7204, and in the thirty-first embodiment the main CPU63. A function of executing the processing of step S7508 in step S7508, and a function of executing the processing of steps S7808 and S7810 in the main CPU 63 in the thirty-second embodiment).

According to the feature X1, the first predetermined storage area and the second predetermined storage area are provided, the first predetermined storage area is treated as a storage area dedicated to the first predetermined processing, and the second predetermined storage area is It is treated as a dedicated storage area for the second predetermined process. As a result, it becomes possible to clearly make the storage destination of the information in the predetermined storage means different between the first predetermined processing and the second predetermined processing. Therefore, when one of the first predetermined process and the second predetermined process is executed, it is possible to prevent the information used in the other process from being erased.

Further, when the erasing trigger occurs, the information erasing process is executed on the second predetermined storage area, so that the second predetermined storage area is generated despite some abnormality in the second predetermined storage area. It is possible to prevent the second predetermined process from being executed in a state where the above information is held as it is. Further, since the information erasing process is executed in the second predetermined process, it is possible to prevent the first predetermined process from intervening in updating the information in the second predetermined storage area.

Feature X2. The erasing execution means executes the erasing process of the information on the second predetermined storage area while preventing the non-erasing target information (management monitoring flag, return address information, information of various registers) from being erased. The gaming machine according to feature X1.

According to the feature X2, the erasing process of the information in the second predetermined storage area is performed while preventing the non-erasure target information in the second predetermined storage area from being erased. As a result, it becomes possible to execute the information erasing process on the second predetermined storage area while preventing even the necessary information from being erased.

Feature X3. The second predetermined processing execution means is configured to perform the second predetermined processing when the first predetermined processing is being executed, the second predetermined processing is being executed, or the second predetermined processing is being executed. A storage executing means (in the thirtieth embodiment, which stores the return correspondence information (return address information, information of various registers) necessary for returning to the situation in which the first predetermined processing is executed in the second predetermined storage area. Function of executing the processing of steps S7102 to S7107 in the main CPU 63, function of executing the processing of steps S7502 to S7507 in the main CPU 63 in the 31st embodiment, and step S7802 of the main CPU 63 in the 32nd embodiment. A function for executing the processing of step S7807),
The game according to the feature X2, wherein the erasing execution means performs the erasing process of the information on the second predetermined storage area while preventing the return corresponding information from being erased as the non-erasing target information. Machine.

According to the feature X3, the second predetermined process is performed while preventing even the restoration correspondence information necessary for returning from the situation in which the second predetermined process is being performed to the situation in which the first predetermined process is being performed. It is possible to execute the information erasing process for the storage area.

Feature X4. The storage executing means stores, in the second predetermined storage area, information on a return address of a program when the second predetermined processing is terminated and the processing returns to the first predetermined processing, as the return correspondence information. The gaming machine described in Feature X3.

According to the feature X4, the information erasing process is executed on the second predetermined storage region while the information at the return address of the program is not erased when returning to the first predetermined process, and thus the second predetermined storage region is executed. Even if the information erasing process is executed for the above, it is possible to return to the predetermined program in the first predetermined process when the second predetermined process is completed.

Feature X5. The control unit is configured to temporarily store information in an internal storage unit (register of the main CPU 63) when executing processing,
The game machine according to feature X3 or X4, wherein the storage execution means stores the information stored in the internal storage means in the second predetermined storage area as the return correspondence information.

According to the feature X5, since the information erasing process is executed on the second predetermined storage area while the information in the internal storage means used in the first predetermined process is not erased, the second predetermined storage area is stored. On the other hand, even if the information erasing process is executed, the information used in the first predetermined process can be restored to the internal storage means when the second predetermined process is completed.

Feature X6. The erasing execution means causes the erasing process of the information to be executed on the second predetermined storage area as the occurrence of the erasure trigger based on the occurrence of an abnormality in the second predetermined storage area. The gaming machine according to any one of the features X1 to X5.

According to the feature X6, since the information erasing process is executed for the second predetermined storage area based on the occurrence of the abnormality in the second predetermined storage area, an abnormality occurs in the second predetermined storage area. It is possible to prevent the second predetermined process from being executed in the state of being kept.

Feature X7. The second predetermined processing execution means is means for monitoring whether or not the second predetermined storage area is normal as the second predetermined processing (in the thirtieth embodiment, steps S7201 to S7203 in the main CPU 63). The game machine according to feature X6, which is provided with a function of executing processing.

According to the feature X7, not only the information erasing process for the second predetermined storage area, but also the monitoring of whether the second predetermined storage area is normal or not can be performed by the second predetermined processing without intervening the first predetermined processing. Since it is executed, it is possible to monitor whether or not the second predetermined storage area is normal and execute the information erasing process for the second predetermined storage area as a series of processes in the second predetermined process. ..

Feature X8. The first predetermined process includes a process for controlling the progress of the game,
The game machine according to any one of features X1 to X7, wherein the second predetermined process includes a process for managing a game history.

According to the feature X8, the process for controlling the progress of the game is executed as the first predetermined process, and the process for managing the game history is executed as the second predetermined process to control the progress of the game. It is possible to prevent the information used in the process for managing the game history from being rewritten when executing the process.

Feature X9. The second predetermined storage area is a history storage area (normal counter area 231 and opening/closing execution mode counter area 232) in which history information of a game corresponding to a predetermined event generated when a game is executed is stored. , The high-frequency support mode counter area 233) is provided, the gaming machine according to Feature X8.

According to the feature X9, when a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage area. As a result, it becomes possible to store and hold information for managing the number of occurrences or the frequency of occurrence of a predetermined event in the gaming machine, and it is preferable to manage the frequency of occurrence of the predetermined event by using this managed information. It becomes possible to do it. Further, since the history information is stored in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, a process for controlling the progress of the game is executed as the first predetermined process, and a process for managing the game history is executed as the second predetermined process, whereby a process for controlling the progress of the game is executed. It is possible to prevent the information stored in the history storage area from being rewritten during execution.

Feature X10. The second predetermined process execution means uses the history information stored in the history storage area to derive mode information corresponding to the result of the game in a predetermined period (step S4208 in the main CPU 63). The game machine according to the feature X9, which is provided with a function of executing the processing of.

According to the feature X10, by using the history information stored in the history storage area, the form information corresponding to the result of the game in the predetermined period is derived, and the management of the game history such as the occurrence frequency of the predetermined event is performed. It is possible to grasp the result.

Feature X11. The gaming machine according to Feature X10, wherein the second predetermined storage area includes a mode information storage area (calculation result storage area 234) that stores the mode information derived by the information deriving unit.

According to the feature X11, when the form information corresponding to the result of the game in the predetermined period is derived using the history information, the form information is stored in the form information storage area. Thereby, it becomes possible to grasp the management result of the game history at an arbitrary timing. Further, a process for controlling the progress of the game is executed as the first predetermined process, and a process for managing the game history is executed as the second predetermined process, whereby a process for controlling the progress of the game is executed. It is possible to prevent the information stored in the mode information storage area from being rewritten during execution.

In addition, with respect to the configurations of the features X1 to X11, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, Any one or a plurality of configurations of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature Y group>
Feature Y1. A control means (main CPU 63) for executing various processes is provided,
The control means is
A first predetermined process executing means (a function of executing a process other than the management execution process in the main CPU 63 in the fifteenth to thirty-fourth embodiments) for executing a first predetermined process among the various processes;
A second predetermined process executing means (a function of executing a management execution process in the main CPU 63 in the fifteenth to thirty-fourth embodiments) for executing a second predetermined process among the various processes;
A first predetermined storage area (a work area 221 for specific control, a stack area 222 for specific control) in which information is stored when the first predetermined processing is executed;
A second predetermined storage area (a work area 223 for non-specific control, a stack area 224 for non-specific control) in which information is stored when the second predetermined processing is executed;
First calculating means for calculating first reference numerical value information corresponding to a plurality of pieces of information stored in the first predetermined storage area (in the thirtieth embodiment, the main CPU 63 executes steps S6604 and S6710). Function, a function of executing the process of step S7304 in the main CPU 63 in the 31st embodiment, and a function of executing the process of step S7610 and step S7701 in the main CPU 63 in the 32nd embodiment).
A gaming machine characterized by being equipped with.

According to the feature Y1, the first predetermined storage area and the second predetermined storage area are provided, the first predetermined storage area is treated as a storage area dedicated to the first predetermined processing, and the second predetermined storage area is It is treated as a dedicated storage area for the second predetermined process. As a result, it becomes possible to clearly make the storage destination of the information in the predetermined storage means different between the first predetermined processing and the second predetermined processing. Therefore, when one of the first predetermined process and the second predetermined process is executed, it is possible to prevent the information used in the other process from being erased. In this case, the first reference numerical value information corresponding to the plurality of pieces of information stored in the first predetermined storage area is calculated. By using the first reference numerical value information, it is possible to specify whether or not the information abnormality has occurred only in the first predetermined storage area.

Feature Y2. Information erasing means for causing information erasing processing to be executed for the first predetermined storage area based on the fact that an abnormality has been identified with respect to the first reference numerical value information calculated by the first calculating means. (A function for executing the process of step S6607 in the main CPU 63 in the thirtieth embodiment, a function for executing the processes of step S7401 and step S7402 in the main CPU 63 in the thirty-first embodiment, and a main side in the thirty-second embodiment. The gaming machine according to feature Y1, which is provided with the function of executing the processing of steps S7704 and S7705 in the CPU 63.

According to the characteristic Y2, when the occurrence of an abnormality is specified with respect to the first reference numerical value information, the information erasing process is executed for the first predetermined storage area. Instead, it is possible to prevent the first predetermined process from being executed while the information in the first predetermined storage area is held as it is.

Feature Y3. The first calculation means,
A first power failure calculating means for calculating the first reference numerical value information when the supply of the operating power to the control means is stopped (in the thirtieth embodiment, a function of executing the process of step S6710 in the main CPU 63, In the 32nd embodiment, a function of executing the process of step S7610 in the main CPU 63),
A first power-on-time calculation unit that calculates the first reference numerical value information when the supply of operating power to the control unit is started (in the thirtieth embodiment, a function of executing the process of step S6604 in the main CPU 63). A function of executing the process of step S7304 in the main CPU 63 in the 31st embodiment, and a function of executing the process of step S7701 in the main CPU 63 in the 32nd embodiment).
Equipped with
The information erasing means is based on the fact that the first reference numerical value information calculated by the first power failure time calculating means and the first reference numerical value information calculated by the first power-on time calculating means do not match. The gaming machine according to feature Y2, wherein the erasing process of the information is executed at least in the first predetermined storage area.

According to the feature Y3, it is possible to specify whether or not the information in the first predetermined storage area is stored and held with the situation where the supply of the operating power is stopped sandwiched by calculating the first reference numerical value information. Becomes Then, when the information in the first predetermined storage area is not stored and held with the supply of the operating power stopped, the information erasing process is executed for the first predetermined storage area. It is possible to prevent the first predetermined process from being executed in a state where the information in the first predetermined storage area is held as it is, despite the occurrence of.

Feature Y4. The information erasing means does not execute the erasing process of the information in the second predetermined storage area even if the occurrence of an abnormality is specified with respect to the first reference numerical value information calculated by the first calculating means. The gaming machine according to the feature Y2 or Y3.

According to the feature Y4, when the occurrence of an abnormality is specified with respect to the first reference numerical value information, the information erasing process is performed on the first predetermined storage area, while the information is erased on the second predetermined storage area. The process is not executed. This makes it possible to prevent even the information in the second predetermined storage area from being erased in a situation where information abnormality has occurred in the first predetermined storage area.

Feature Y5. The gaming machine according to any one of features Y1 to Y4, wherein the first reference numerical value information is information that does not change according to the information stored in the second predetermined storage area.

According to the feature Y5, in the configuration in which the first predetermined storage area and the second predetermined storage area exist, it is possible to individually specify the information abnormality relating to the first predetermined storage area using the first reference numerical value information. It will be possible.

Feature Y6. It is provided with a second calculating means (a function of executing the processing of steps S7611 and S7706 in the main CPU 63) for calculating the second reference numerical value information corresponding to the plurality of pieces of information stored in the second predetermined storage area. The gaming machine according to any one of the features Y1 to Y5.

According to the characteristic Y6, the second reference numerical value information corresponding to the plurality of pieces of information stored in the second predetermined storage area is calculated. By using the second reference numerical value information, it becomes possible to specify whether or not the information abnormality has occurred only in the second predetermined storage area.

Feature Y7. Means for causing information erasing processing to be executed on at least the second predetermined storage area based on the fact that an abnormality has been identified with respect to the second reference numerical value information calculated by the second calculating means ( The gaming machine according to feature Y6, which is provided with a function of executing the processes of steps S7808 and S7810 in the main CPU 63.

According to the characteristic Y7, when the occurrence of an abnormality is specified with respect to the second reference numerical value information, the information erasing process is executed on the second predetermined storage area. Instead, it is possible to prevent the second predetermined process from being executed while the information in the second predetermined storage area is retained as it is.

Feature Y8. The first predetermined process includes a process for controlling the progress of the game,
The game machine according to any one of features Y1 to Y7, wherein the second predetermined process includes a process for managing a game history.

According to the feature Y8, the process for controlling the progress of the game is executed as the first predetermined process, and the process for managing the game history is executed as the second predetermined process to control the progress of the game. It is possible to prevent the information used in the process for managing the game history from being rewritten when executing the process.

Feature Y9. The second predetermined storage area is a history storage area (normal counter area 231 and opening/closing execution mode counter area 232) in which, when a predetermined event occurs due to execution of a game, history information of the game corresponding thereto is stored. , The high-frequency support mode counter area 233) is provided, the gaming machine according to the feature Y8.

According to the feature Y9, when a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage area. As a result, it becomes possible to store and hold information for managing the number of occurrences or the frequency of occurrence of a predetermined event in the gaming machine, and it is preferable to manage the frequency of occurrence of the predetermined event by using this managed information. It becomes possible to do it. Further, since the history information is stored in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, a process for controlling the progress of the game is executed as the first predetermined process, and a process for managing the game history is executed as the second predetermined process, whereby a process for controlling the progress of the game is executed. It is possible to prevent the information stored in the history storage area from being rewritten during execution.

Feature Y10. The second predetermined processing execution means uses the history information stored in the history storage area to derive mode information corresponding to the result of the game in a predetermined period (step S4208 in the main CPU 63). The game machine according to the feature Y9, which is provided with a function of executing the process of.

According to the feature Y10, by using the history information stored in the history storage area, the form information corresponding to the result of the game in the predetermined period is derived, and the management of the game history such as the occurrence frequency of the predetermined event is performed. It is possible to grasp the result.

Feature Y11. The gaming machine according to feature Y10, wherein the second predetermined storage area includes a mode information storage area (calculation result storage area 234) that stores the mode information derived by the information deriving means.

According to the characteristic Y11, when the form information corresponding to the result of the game in the predetermined period is derived using the history information, the form information is stored in the form information storage area. Thereby, it becomes possible to grasp the management result of the game history at an arbitrary timing. Further, a process for controlling the progress of the game is executed as the first predetermined process, and a process for managing the game history is executed as the second predetermined process, whereby a process for controlling the progress of the game is executed. It is possible to prevent the information stored in the mode information storage area from being rewritten during execution.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features Y1 to Y11. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, Any one or a plurality of configurations of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the characteristic T group, the characteristic U group, the characteristic V group, the characteristic W group, the characteristic X group, and the characteristic Y group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, various controls need to be suitably performed, and there is still room for improvement in this respect.

<Feature Z group>
Feature Z1. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (a function for executing the setting value updating process in the main CPU 63),
Status generating means (a function of executing the processing of steps S7905, S7916 and S7917 in the main CPU 63) for setting a status in which the setting value to be used can be changed.
In the situation where the supply of the operating power to the control means (main CPU 63) having the setting means is started and the process at the start of the supply is being executed, the setting value of the use target in the situation where the setting is not possible is set. A setting informing means (a function for executing the setting confirmation process in the main CPU 63) for informing.
A gaming machine characterized by being equipped with.

According to the characteristic Z1, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player is allowed to use the more advantageous setting value. Will be expected. In this case, in order to confirm the set value set as the usage target, it is necessary to temporarily stop the supply of the operating power to the control means and then restart the supply of the operating power to the control means. .. As a result, it becomes possible to make it difficult to perform an act of illegally confirming the set value. Moreover, since the setting value is notified in the situation where the process at the start of supply is being executed, it is not necessary to notify the setting value in the situation where the game is interrupted. Therefore, it is possible to preferably notify the set value.

Feature Z2. The gaming machine according to feature Z1, wherein the situation generating means sets the setting possible situation in a situation where the processing at the start of supply is being executed.

According to the feature Z2, the setting possible situation in which the setting value to be used can be set, and the situation in which the setting value to be used is notified in a situation that is not the setting possible situation are set at the start of supply. It is possible to aggregate the situation where the processing is being executed.

Feature Z3. A first specifying means (a function of executing the processes of steps S7912 and S7916 in the main CPU 63) for specifying the occurrence of the first trigger event;
The setting notification unit can perform the setting based on the situation where the process at the start of supply is being executed and the occurrence of the first trigger event is identified by the first identifying unit. The gaming machine according to feature Z1 or Z2, characterized in that the setting value of the use target in a situation other than the situation is notified.

According to the feature Z3, in order to notify the set value of the target to be used, it is necessary not only to start the supply of the operating power to the control means but also to generate the first trigger event. As a result, it becomes possible to make it difficult to perform an act of illegally confirming the set value.

Feature Z4. The gaming machine according to feature Z3, wherein the first trigger event is that a predetermined operation is performed on the setting key inserting unit (setting key inserting unit 68a) with the setting key.

According to the feature Z4, in order to notify the setting of the use target, it is necessary to perform a predetermined operation with the setting key on the setting key insertion portion. As a result, it becomes possible to make it difficult to perform an act of illegally confirming the set value.

Feature Z5. The setting notification means is in a situation where the process at the start of supply is being executed and the occurrence of the first trigger event is specified by the first specifying means, and the notification condition is satisfied. In such a case, the notification of the setting value of the use target in a situation that is not the setting possible situation is performed,
The setting condition is satisfied based on that the situation occurrence means is in a situation where the process at the start of supply is being executed and the occurrence of the first trigger event is identified by the first identifying means. If you do so, it will be in the setting possible situation,
The gaming machine according to feature Z3 or Z4, wherein the notification condition and the setting condition are different.

According to the feature Z5, not only is the supply of operating power to the control means started, but the first trigger event is generated, regardless of whether the settable status is generated or the setting value to be used is notified. Need to occur. As a result, it is possible to make it difficult to perform both the act of setting the setting value to be used due to fraud and the act of checking the setting value to be used due to fraud. On the other hand, since the setting condition for generating the settable condition and the notification condition for notifying the set value of the use target are different, the settable condition and the situation where the set value of the use target is notified It is possible to generate either one of them independently.

Feature Z6. A second specifying unit (a function of executing the process of step S7905 in the main CPU 63) for specifying the occurrence of the second trigger event is provided,
The setting condition is a situation in which the occurrence of the first trigger event is identified by the first identifying means in a situation in which the process at the start of supply is being performed, It is established based on the situation that the occurrence of the trigger event is specified,
The notification condition is a situation in which the occurrence of the first trigger event is identified by the first identifying means in a situation in which the process at the start of supply is being executed, The gaming machine according to feature Z5, which is established based on a situation in which the occurrence of the trigger event is not specified.

According to the feature Z6, in order to generate the settable condition, it is necessary to start the supply of the operating power to the control means and generate the second trigger event as well as the first trigger event. As a result, in both cases of setting the setting value to be used and notifying the setting value of the usage target, it is not only necessary to start supplying the operating power to the control means. In the configuration in which it is necessary to generate the first trigger event, the operation for generating the settable status can be made more complicated. Therefore, it becomes possible to more intensively prevent the act of illegally setting the setting value to be used.

Feature Z7. The gaming machine according to feature Z6, wherein the second trigger event is that a predetermined operation means (reset button 68c) is operated.

According to the feature Z7, in order to generate the settable state, it is necessary to start the supply of the operating power to the control means and generate the first trigger event, and also to operate the predetermined operation means. This makes it difficult to illegally set the setting value to be used, but prevents the operation for legally generating the settable status from becoming excessively complicated. It becomes possible.

Feature Z8. An information erasing unit that executes an information erasing process based on a situation in which the occurrence of the second trigger event is identified by the second identifying unit in the situation in which the process at the start of supply is being performed ( The gaming machine according to feature Z6 or Z7, which is provided with a function of executing the process of step S7915 in the main CPU 63.

According to the feature Z8, the condition for generating the settable status by using the second trigger event necessary for executing the information erasing process and the set value of the usage target in the situation that is not the settable status It is possible to make the condition different from the condition for making the notification.

Feature Z9. The gaming machine according to feature Z8, wherein the information erasing means executes the erasing process of the information even when the setting possible situation occurs.

According to the feature Z9, it is possible to execute the information erasing process when the setting possible situation is reached.

Feature Z10. A situation in which the occurrence of the second trigger event is identified by the second identifying unit in a situation in which the process at the start of supply is being performed, and the occurrence of the first trigger event is identified by the first identifying unit. The game machine according to the feature Z8 or Z9, characterized in that, in a situation where the setting is not possible, the information erasing process is executed by the information erasing means although the setting is not possible.

According to the characteristic Z10, depending on whether or not the first trigger event is generated when the supply of the operating power to the control means is started, the information erasing process is executed and the setting possible state is set, and It is possible to select whether or not the erasing process is executed but the settable status does not occur.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features Z1 to Z10. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, Any one or a plurality of configurations of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature a group>
Features a1. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (a function for executing the setting value updating process in the main CPU 63),
Status generating means (a function of executing the processing of steps S7905, S7916 and S7917 in the main CPU 63) for setting a status in which the setting value to be used can be changed.
Information erasing means for executing information erasing processing (function of executing the processing of step S7915 in the main CPU 63),
Setting informing means (a function for executing setting confirmation processing in the main CPU 63) for informing the setting value of the use target in a situation other than the setting possible situation;
First specifying means for specifying the occurrence of the first trigger event (a function of the main CPU 63 for executing the processing of steps S7912 and S7916);
Second identifying means for identifying the occurrence of the second trigger event (a function of the main CPU 63 for executing the processing of step S7905);
Equipped with
The situation occurrence means identifies the occurrence of the first trigger event by the first identification means in a situation where the supply of operating power to the control means having the setting means is started and the processing at the start of supply is being executed. Based on the fact that the occurrence of the second trigger event is specified by the second specifying means, the setting possible status is set.
The information erasing means is based on the fact that the occurrence of the second trigger event is identified by the second identifying means in the situation where the processing at the start of supply is being executed, and the information erasing processing is performed. Run
A situation in which the occurrence of the second trigger event is identified by the second identifying means in the situation in which the process at the start of supply is being performed, and the occurrence of the first trigger event is identified by the first identifying means. If not, the information erasing process by the information erasing means is executed although the setting is not possible.
The setting notifying means is in a situation in which the occurrence of the first trigger event is identified by the first identifying means in a situation in which the process at the start of supply is being executed, and A gaming machine characterized in that, based on a situation in which the occurrence of a triggering event is not specified, a notification of the setting value of the use target in a situation that is not the setting possible situation is performed.

According to the characteristic a1, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player is allowed to use the more advantageous setting value. Will be expected. Further, since the information erasing process can be executed, it is possible to prevent the game from being played despite the occurrence of the information abnormality. Further, since the set value set as the usage target can be notified, it is possible to confirm the set value.

In this case, in order to confirm the set value set as the usage target, it is necessary to start the supply of the operating power to the control means and generate the first trigger event. As a result, it becomes possible to make it difficult to perform an act of illegally confirming the set value.

Further, in order to generate the settable status, it is necessary to start the supply of the operating power to the control means and generate the second trigger event as well as the first trigger event. As a result, in both cases of setting the setting value to be used and notifying the setting value of the usage target, it is not only necessary to start supplying the operating power to the control means. In the configuration in which it is necessary to generate the first trigger event, the operation for generating the settable status can be made more complicated. Therefore, it becomes possible to more intensively prevent the act of illegally setting the setting value to be used.

In addition, the second trigger event necessary for executing the information erasing process is used to notify the condition for generating the settable status and the setting value of the usage target in the situation that is not the settable status. It becomes possible to differ from the conditions for doing so.

In addition, depending on whether or not the first trigger event is generated when the supply of the operating power to the control means is started, the information erasing process is executed and the setting possible state and the information erasing process are performed. It is possible to select whether to be executed but not settable.

Feature a2. The gaming machine according to feature a1, wherein the first triggering event is that a predetermined operation is performed on the setting key inserting unit (setting key inserting unit 68a) with the setting key.

According to the feature a2, in order to notify the setting of the use target, it is necessary to perform a predetermined operation with the setting key on the setting key insertion portion. As a result, it becomes possible to make it difficult to perform an act of illegally confirming the set value.

Feature a3. The gaming machine according to feature a1 or a2, wherein the second trigger event is that a predetermined operation means (reset button 68c) is operated.

According to the feature a3, in order to generate the settable condition, it is necessary to start the supply of the operating power to the control means and generate the first trigger event, and also to operate the predetermined operation means. This makes it difficult to illegally set the setting value to be used, but prevents the operation for legally generating the settable status from becoming excessively complicated. It becomes possible.

For the configurations of the features a1 to a3, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the inventions related to the characteristic Z group and the characteristic a group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine such as the above example, a configuration capable of suitably confirming the setting value that determines the advantage of the gaming machine is required, and there is still room for improvement in this respect. ..

<Feature b group>
Features b1. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (a function for executing the setting value updating process in the main CPU 63),
Status generating means (a function of executing the processing of steps S7905, S7916 and S7917 in the main CPU 63) for setting a status in which the setting value to be used can be changed.
A setting monitoring unit that executes a setting monitoring process for monitoring whether or not the setting value of the use target is abnormal (a function of the main CPU 63 that executes the process of step S8202);
Equipped with
A gaming machine characterized in that the setting monitoring processing is not included in the processing at the start of supply, which is executed when the supply of operating power to the control means having the setting means is started.

According to the feature b1, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the degree of advantage of the player, the player is allowed to use the more advantageous setting value. Will be expected. Further, since the setting monitoring process for monitoring whether or not the setting value of the usage target is abnormal is performed, it is possible to deal with it when the setting value of the usage target is abnormal. Further, since the setting monitoring process is not included in the process at the start of supply, it is possible to achieve the above-described excellent effects while preventing the processing load of the process at the start of supply from increasing.

Feature b2. The gaming machine according to feature b1, wherein the situation generation means generates the setting possible situation in a situation where the processing at the start of supply is being executed.

According to the feature b2, since the setting possible situation occurs in the situation where the process at the start of supply is being executed, it becomes possible to set the set value of the use target before the game is started. .. In this case, since the set value to be used is set in the process at the start of supply, the processing load of the process at the start of supply is correspondingly increased. On the other hand, since the process at the start of supply does not include the setting monitoring process because of the configuration of the characteristic b1 described above, the processing load of the process at the start of supply is prevented from further increasing while being used. It is possible to monitor whether or not the set value is abnormal.

Feature b3. The gaming machine according to feature b1 or b2, wherein the setting monitoring unit executes the setting monitoring process after the process at the start of supply is completed.

According to the feature b3, since the setting monitoring process is executed after the process at the start of supply is completed, the setting value of the use target is abnormal while preventing the processing load of the process at the start of supply from increasing. It becomes possible to monitor whether or not.

Feature b4. The gaming machine according to feature b3, wherein the setting monitoring unit executes the setting monitoring process each time a monitoring trigger occurs after the process at the start of supply is completed.

According to the feature b4, since the setting monitoring process is executed every time a monitoring trigger occurs after the process at the start of supply is completed, it is easy to specify that the setting value to be used is abnormal.

Feature b5. A means for executing an interrupt process that is regularly activated (a function for executing a first timer interrupt process in the main CPU 63),
The gaming machine according to any one of features b1 to b4, wherein the setting monitoring process is included in the interrupt process.

According to the feature b5, since the setting monitoring process is executed every time it is activated, it is possible to increase the frequency of monitoring whether or not the setting value to be used is abnormal.

Feature b6. The setting monitoring means controls the progress of the game based on the fact that the setting value of the use target is abnormal in the setting monitoring processing (step S8207 in the main CPU 63 and The game machine according to any one of features b1 to b5, which is provided with a function of executing the process of step S8302.

According to the feature b6, when it is specified that the set value of the use target is abnormal, the progress of the game is restricted, so that the game is continued even though the set value of the use target is abnormal. It becomes possible not to.

Feature b7. Based on the fact that the setting monitoring means identifies that the setting value of the use target is abnormal in the setting monitoring process, a notification is made to enable the player to recognize that the setting possible situation should be generated. The gaming machine described in any one of the features b1 to b6, which is provided with a means (a function of executing the process of step S8303 in the main CPU 63) to be executed.

According to the feature b7, when it is specified that the setting value of the use target is abnormal, a notification is made to enable the player to recognize that the setting possible situation should be generated, and thus the setting of the use target is performed. When the value becomes abnormal, it is possible to urge the manager of the game hall to cancel it.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features b1 to b7. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the above-mentioned feature b group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, it is necessary to appropriately manage the setting value that determines the advantage of the gaming machine, and there is still room for improvement in this respect.

<Characteristic c group>
Feature c1. Predetermined display means (first to fourth notification display devices 201 to 204);
A predetermined display control means (a function for executing a second timer interrupt process in the main CPU 63) for controlling the display of the predetermined display means;
Equipped with
The predetermined display control means causes the predetermined display means to perform a check display for confirming whether or not the predetermined display means is normal based on the occurrence of the check trigger (the 35th control means). In the embodiment, the main CPU 63 has a function of executing the process of step S9102, and the thirty-eighth embodiment has a function of executing the process of step S9602 in the main CPU 63).

According to the feature c1, the check display is displayed on the predetermined display means based on the occurrence of the check trigger. This makes it possible to confirm whether or not the predetermined display means is normal.

Feature c2. The predetermined display means has a plurality of light emitting parts (display segments 321 to 324),
The gaming machine according to feature c1, wherein the check display is a display that enables confirmation that each of the plurality of light emitting units can be in a light emitting state.

According to the feature c2, each of the plurality of light emitting units of the predetermined display means is in a light emitting state as a check display. This makes it possible to confirm whether or not each of the plurality of light emitting units of the predetermined display means is in the light emitting state.

Feature c3. The gaming machine according to feature c1 or c2, wherein the check trigger is generated when supply of operating power is started.

According to the characteristic c3, since the check display is performed when the supply of the operating power is started, it is possible to quickly confirm whether or not the predetermined display means is normal.

Feature c4. The gaming machine according to any one of features c1 to c3, wherein the check trigger is generated each time supply of operating power is started.

According to the characteristic c4, it is possible to confirm whether or not the predetermined display means is normal every time the supply of the operating power is started.

Feature c5. The gaming machine according to any one of features c1 to c4, wherein the check trigger is generated without requiring an operation for generating the check trigger when supply of operating power is started.

According to the feature c5, when the supply of the operating power is started, the check display is displayed without requiring a special operation, which makes it easy to confirm whether or not the predetermined display means is normal. It becomes possible to do.

Feature c6. The check control means causes the predetermined display means to perform the check display when the supply of the operating power is started and the check trigger is generated, and the supply of the operating power is started. The gaming machine according to any one of the features c1 to c5, wherein the check display is not displayed on the predetermined display means when the check trigger has not occurred.

According to the characteristic c6, since the check display is performed when the supply of the operating power is started and the check opportunity is generated, the predetermined display is provided at the stage before the game is started on the gaming machine. It is possible to confirm whether or not the means is normal. On the other hand, even if the supply of operating power is started, the check display is not displayed if the check trigger has not occurred, so the check display is displayed in the situation where it is not necessary to display the check display. It becomes possible not to.

Feature c7. A means (a function of executing the process of step S8606 in the main CPU 63) for storing information in the use correspondence storage means (management start flag) based on the fact that the gaming machine is used in a predetermined mode,
The check control means generates the check trigger when the supply of operating power is started and the information stored in the use correspondence storage means does not correspond to the use correspondence information. When the predetermined display means is caused to perform the check display and the supply of operating power is started and the information stored in the use correspondence storage means corresponds to the use correspondence information. The gaming machine according to feature c6, wherein the check display is not displayed on the predetermined display means because the check trigger has not occurred.

According to the feature c7, when the supply of the operating power is started until the game machine is used in the predetermined mode, the check display is displayed on the predetermined display means, and the game machine is used in the predetermined mode. Even if the supply of the operating power is started based on this, the check display is not displayed on the predetermined display means. Thus, for example, in the shipping stage of the gaming machine, when the supply of the operating power is started, the check display is displayed on the predetermined display means, thereby determining whether or not the predetermined display means is normal. This makes it possible to confirm and even if the supply of operating power is started after the gaming machine is installed in the game hall, it is possible to prevent the check display from being displayed on the predetermined display means.

Feature c8. The check control means,
Display ending means for ending the check display on the predetermined display means based on the occurrence of an ending trigger (a function of executing the processing of step S9002 in the main CPU 63 and a negative determination in step S9101),
Canceling means for terminating the check display on the predetermined display means based on the occurrence of the cancellation trigger even if the termination trigger has not occurred (function of executing the process of step S9203 in the main CPU 63, and A function of making a negative judgment in step S9101, a function of executing the process of step S9308 in the main CPU 63, and a function of making a negative judgment in step S9101),
The gaming machine according to any one of the features c1 to c7, which is characterized by comprising:

According to the feature c8, the check display is terminated based on the cancellation trigger even if the check display termination trigger has not occurred, so that the check display is being performed on the predetermined display means. Even in this case, it is possible to end the check display halfway and perform another display.

Feature c9. The gaming machine according to feature c8, wherein the cancellation trigger is generated based on an operation of a predetermined operation means (reset button 68c).

According to the feature c9, the cancellation trigger is generated based on the operation of the predetermined operation means, so that it is possible to end the check display at an arbitrary timing.

Feature c10. The predetermined display control means has another display control means (a function of executing the processing of steps S9004 and S9006 in the main CPU 63) that causes another display different from the check display when the separate display execution state is set. Prepare,
The gaming machine according to feature c8 or c9, wherein the cancellation opportunity is generated based on the fact that the separate display execution state is set.

According to the characteristic c10, since the check display is terminated when the cancellation trigger occurs due to the fact that the separate display execution state is set, the separate display can be prioritized over the check display.

Feature c11. Features c1 to c1 which are provided with a unit (a function of executing the process of step S9406 in the main CPU 63) for waiting the progress of the process when the check display is being executed on the predetermined display unit. The gaming machine according to any one of c10.

According to the characteristic c11, since the check display is performed by the predetermined display means in the situation where the progress of the processing is on standby, it is possible to perform the check display while suppressing an increase in the processing load.

Feature c12. The check control means starts the check display on the predetermined display means before the processing for controlling the progress of the game is executed when the supply of the operating power is started. The gaming machine according to any one of c1 to c11.

According to the characteristic c12, when the supply of the operating power is started, it is possible to confirm whether or not the predetermined display means is normal before the game is played on the gaming machine.

Features c13. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (a function for executing the setting value updating process in the main CPU 63),
Means for executing processing at the start of supply of operation power based on start of supply of operation power (in the thirty-fifth embodiment, a function of executing the processing of steps S8801 to S8819 in the main CPU 63, the thirty-sixth embodiment). In the embodiment, a function of executing the processing of steps S9401 to S9420 in the main CPU 63),
Equipped with
A configuration in which predetermined setting-related processing (setting confirmation processing, setting value updating processing) relating to the setting value can be executed in a situation where processing at the start of supply of the operating power is being executed,
The gaming machine according to feature c12, wherein the check control means starts the check display on the predetermined display means in a situation where the process at the start of supplying the operating power is being executed.

According to the characteristic c13, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player can use the more advantageous setting value as the usage target. Will be expected. Further, in a situation where the process at the start of supplying the operating power is being executed, a predetermined setting-related process relating to the set value can be executed. As a result, it becomes possible to execute the setting related processing at a stage before the game is started. In this case, the check display is started by the predetermined display means in a situation where the process at the start of supplying the operating power is being executed. This makes it possible to combine not only the predetermined setting-related processing but also the processing for starting the check display on the predetermined display means with respect to the processing when the supply of the operating power is started.

Feature c14. The check control means starts the check display on the predetermined display means before the timing when the predetermined setting-related processing can be executed (in the thirty-fifth embodiment, steps S8804 and S8805 in the main CPU 63). The game machine according to feature c13, which has a function of performing the process of step S9404 and step S9405 of the main CPU 63 in the thirty-sixth embodiment.

According to the characteristic c14, it is possible to confirm whether or not the predetermined display unit is normal before the predetermined setting-related processing is executed.

Feature c15. The predetermined display control means causes the predetermined display means to display the current setting value when the predetermined setting-related processing is executed (function of executing the processing of steps S9004 and S9006 in the main CPU 63). The gaming machine described in the feature c13 or c14, which is characterized by comprising:

According to the characteristic c15, the current setting value is displayed on the predetermined display means when the predetermined setting-related processing is executed. Therefore, the manager of the gaming hall confirms the predetermined display means to display the current setting value. It becomes possible to grasp. In this case, since the configuration of the characteristic c13 is provided, not only the predetermined setting-related processing but also the processing for starting the check display on the predetermined display means are integrated in the processing when the supply of the operating power is started. , A process at the time of starting the supply of the operating power, the work of confirming the predetermined display means to grasp whether the predetermined display means is normal and the work of confirming the predetermined display means to grasp the current set value It becomes possible to carry out collectively in the situation where is executed.

Further, in the case where the configuration of the characteristic c14 is provided, since the check display is started on the predetermined display means before the current set value is displayed on the predetermined display means, the predetermined display means is normal. After confirming whether or not it is possible to confirm the current set value by using the predetermined display means. This makes it possible to accurately confirm the set value.

Feature c16. The check control means,
Means for starting the check display on the predetermined display means before the timing at which the predetermined setting-related processing can be executed (a function of the main CPU 63 for executing the processing of steps S8804 and S8805);
Means for ending the check display based on the occurrence of a cancellation trigger in the predetermined setting-related processing in the situation where the check display is being performed (function and step for executing the process of step S9203 in the main CPU 63) A function of making a negative judgment in S9101, a function of executing the processing of step S9308 in the main CPU 63, and a function of making a negative judgment in step S9101),
The gaming machine according to feature c15, which is provided with.

According to the characteristic c16, since the check display is started on the predetermined display means before the current set value is displayed on the predetermined display means, after confirming whether the predetermined display means is normal or not. It is possible to confirm the current set value by using the predetermined display means. This makes it possible to accurately confirm the set value. Further, in the situation where the check display is being performed, a predetermined setting-related process is executed, and the check display is ended based on the occurrence of a cancellation trigger. As a result, when a predetermined setting-related process is executed, the check display can be ended and the current setting value can be displayed on the predetermined display means without waiting for the check display to be ended. It will be possible. Therefore, it becomes possible to confirm the current set value at an early stage.

Feature c17. The gaming machine according to feature c16, wherein the cancellation opportunity is generated based on an operation of a predetermined operation means (reset button 68c).

According to the feature c17, the cancellation trigger is generated based on the operation of the predetermined operation means, so that the check display can be ended at an arbitrary timing.

Feature c18. As the predetermined setting-related processing, a means for executing processing for setting a setting-enabled state in which the setting value to be used can be changed (in the thirty-fifth embodiment, a step in the main CPU 63). S8806, a function of making a positive determination in steps S8817 and S8818, and a function of making a positive determination in steps S9407, S9418 and S9419 in the main CPU 63 in the thirty-sixth embodiment. The gaming machine according to any one of the features c13 to c17.

According to the characteristic c18, not only the processing for setting the setting value to be used but also the processing for starting the check display on the predetermined display means are integrated with respect to the processing at the start of the supply of the operating power. It becomes possible.

Feature c19. The setting means updates the set value to be used based on the operation of the predetermined operation means (reset button 68c) in the setting possible state,
The check control means,
Means for starting the check display on the predetermined display means before the setting possible state (function of executing the processing of steps S8804 and S8805 in the main CPU 63);
A means for ending the check display based on the operation of the predetermined operation means in the setting possible status in the situation where the check display is being performed (the processing of step S9203 in the main CPU 63 is executed). A function and a function of making a negative determination in step S9101, a function of executing the process of step S9308 in the main CPU 63, and a function of making a negative determination in step S9101).
Equipped with
The predetermined display control means executes the processing of step S9004 and step S9006 in the main CPU 63 after displaying the check display in the settable status, and causing the predetermined display means to display the current set value. The game machine according to feature c18, which is characterized by having a function of

According to the feature c19, since the check display is started on the predetermined display means before the current set value is displayed on the predetermined display means, after confirming whether the predetermined display means is normal or not. It is possible to confirm the current set value by using the predetermined display means. This makes it possible to accurately confirm the set value. In addition, when the display for checking is being performed, the setting display state is set, and the display for checking is ended based on the operation of the predetermined operation means, and the current set value is displayed. This makes it possible to terminate the check display and display the current set value on the predetermined display means without waiting for the check display to be terminated when the settable status is reached. .. Therefore, it becomes possible to confirm the current set value at an early stage.

Furthermore, in the configuration in which the set value to be used is updated based on the operation of the predetermined operation means in the settable situation, the check display is displayed based on the operation of the predetermined operation means in the settable situation. Since the current setting value is displayed after the completion, the dedicated operation for terminating the check display and displaying the current setting value is not required. Therefore, it is possible to improve the workability of the work for updating the setting value to be used.

Feature c20. As the predetermined setting-related processing, there is provided means for executing processing for displaying the current setting value on the predetermined display means (function for executing setting confirmation processing in the main CPU 63). The gaming machine according to any one of the features c13 to c19.

According to the characteristic c20, not only the process for confirming the current set value but also the process for starting the check display on the predetermined display means can be integrated with the process at the start of the supply of the operating power. It will be possible.

Feature c21. The predetermined display control means is provided with means for displaying information corresponding to the management result of the game history on the predetermined display means (function of executing the processes of steps S8708, S8709 and S9107 in the main CPU 63). The gaming machine according to any one of the features c1 to c20.

According to the characteristic c21, it becomes possible to notify the manager of the game hall of the management result of the game history. In this case, whether or not the information corresponding to the management result of the game history on the predetermined display means is accurately displayed by providing the check display on the predetermined display means with the configuration of the characteristic c1. It becomes possible to confirm.

In addition, with respect to the configurations of the features c1 to c21, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, Any one or a plurality of configurations of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature d group>
Feature d1. Predetermined display means (first to fourth notification display devices 201 to 204);
A predetermined display control means (a function for executing a second timer interrupt process in the main CPU 63) for controlling the display of the predetermined display means;
Equipped with
The predetermined display control means checks whether or not the predetermined display means is normal before the process for controlling the progress of the game is executed when the supply of the operating power is started. Check control means for causing the predetermined display means to display a message (a function of executing the process of step S9102 in the main CPU 63 in the thirty-fifth embodiment, and executing the process of step S9602 in the main CPU63 in the thirty-eighth embodiment. A gaming machine characterized by having functions).

According to the feature d1, it is possible to confirm whether or not the predetermined display means is normal by performing the check display on the predetermined display means. Further, when the supply of the operating power is started, the check display is started before the process for controlling the progress of the game is executed, so that when the supply of the operating power is started, Therefore, it is possible to confirm whether or not the predetermined display means is normal before the game is played.

Feature d2. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (a function for executing the setting value updating process in the main CPU 63),
Means for executing processing at the start of supply of operation power based on start of supply of operation power (in the thirty-fifth embodiment, a function of executing the processing of steps S8801 to S8819 in the main CPU 63, the thirty-sixth embodiment). In the embodiment, a function of executing the processing of steps S9401 to S9420 in the main CPU 63),
Equipped with
A configuration in which predetermined setting-related processing (setting confirmation processing, setting value updating processing) relating to the setting value can be executed in a situation where processing at the start of supply of the operating power is being executed,
The gaming machine according to feature d1, wherein the check control means starts the check display on the predetermined display means in a situation where the process at the start of supplying the operating power is being executed.

According to the characteristic d2, the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage degree of the player, so that the player sets the more advantageous setting value as the usage target. Will be expected. Further, in a situation where the process at the start of supplying the operating power is being executed, a predetermined setting-related process relating to the set value can be executed. As a result, it becomes possible to execute the setting related processing at a stage before the game is started. In this case, the check display is started by the predetermined display means in a situation where the process at the start of supplying the operating power is being executed. This makes it possible to combine not only the predetermined setting-related processing but also the processing for starting the check display on the predetermined display means with respect to the processing when the supply of the operating power is started.

Feature d3. The check control means starts the check display on the predetermined display means before the timing when the predetermined setting-related processing can be executed (in the thirty-fifth embodiment, steps S8804 and S8805 in the main CPU 63). A function of executing the processing of step S9404 and step S9405 of the main CPU 63 in the thirty-sixth embodiment).

According to the characteristic d3, it is possible to confirm whether or not the predetermined display means is normal before the predetermined setting-related processing is executed.

Feature d4. The predetermined display control means causes the predetermined display means to display the current setting value when the predetermined setting-related processing is executed (function of executing the processing of steps S9004 and S9006 in the main CPU 63). The gaming machine described in the feature d2 or d3, characterized in that

According to the feature d4, the current setting value is displayed on the predetermined display means when the predetermined setting-related processing is executed. Therefore, the manager of the gaming hall confirms the predetermined display means to display the current setting value. It becomes possible to grasp. In this case, since the configuration of the characteristic d2 is provided, the processing at the start of the supply of the operating power includes not only the predetermined setting-related processing but also the processing for starting the check display on the predetermined display means. , A process at the time of starting the supply of the operating power, the work of confirming the predetermined display means to grasp whether the predetermined display means is normal and the work of confirming the predetermined display means to grasp the current set value It becomes possible to carry out collectively in the situation where is executed.

In the case where the configuration of the characteristic d3 is provided, the check display is started on the predetermined display means before the current set value is displayed on the predetermined display means, so the predetermined display means is normal. After confirming whether or not it is possible to confirm the current set value by using the predetermined display means. This makes it possible to accurately confirm the set value.

Feature d5. The check control means,
Means for starting the check display on the predetermined display means before the timing at which the predetermined setting-related processing can be executed (a function of the main CPU 63 for executing the processing of steps S8804 and S8805);
Means for ending the check display based on the occurrence of a cancellation trigger in the predetermined setting-related processing in the situation where the check display is being performed (function and step for executing the process of step S9203 in the main CPU 63) A function of making a negative judgment in S9101, a function of executing the processing of step S9308 in the main CPU 63, and a function of making a negative judgment in step S9101),
The gaming machine described in the feature d4, which is characterized by comprising:

According to the characteristic d5, since the check display is started on the predetermined display means before the current set value is displayed on the predetermined display means, after confirming whether the predetermined display means is normal or not. It is possible to confirm the current set value by using the predetermined display means. This makes it possible to accurately confirm the set value. Further, in the situation where the check display is being performed, a predetermined setting-related process is executed, and the check display is ended based on the occurrence of a cancellation trigger. As a result, when a predetermined setting-related process is executed, the check display can be ended and the current setting value can be displayed on the predetermined display means without waiting for the check display to be ended. It will be possible. Therefore, it becomes possible to confirm the current set value at an early stage.

Feature d6. The gaming machine according to feature d5, wherein the cancellation trigger is generated based on an operation of a predetermined operation means (reset button 68c).

According to the characteristic d6, since the cancellation trigger is generated based on the operation of the predetermined operation means, it is possible to end the check display at an arbitrary timing.

Feature d7. As the predetermined setting-related processing, a means for executing processing for setting a setting-enabled state in which the setting value to be used can be changed (in the thirty-fifth embodiment, a step in the main CPU 63). S8806, a function of making a positive determination in steps S8817 and S8818, and a function of making a positive determination in steps S9407, S9418 and S9419 in the main CPU 63 in the thirty-sixth embodiment. The gaming machine described in any one of the features d2 to d6.

According to the characteristic d7, not only the processing for setting the set value to be used but also the processing for starting the check display on the predetermined display means are integrated with respect to the processing at the start of the supply of the operating power. It becomes possible.

Feature d8. The setting means updates the set value to be used based on the operation of the predetermined operation means (reset button 68c) in the setting possible state,
The check control means,
Means for starting the check display on the predetermined display means before the setting possible state (function of executing the processing of steps S8804 and S8805 in the main CPU 63);
A means for ending the check display based on the operation of the predetermined operation means in the setting possible status in the situation where the check display is being performed (the processing of step S9203 in the main CPU 63 is executed). A function and a function of making a negative determination in step S9101, a function of executing the process of step S9308 in the main CPU 63, and a function of making a negative determination in step S9101).
Equipped with
The predetermined display control means executes the processing of step S9004 and step S9006 in the main CPU 63 after displaying the check display in the setting possible state, and causing the predetermined display means to display the current setting value. The gaming machine according to feature d7, which is characterized by having a function of

According to the characteristic d8, since the check display is started on the predetermined display means before the current set value is displayed on the predetermined display means, after confirming whether the predetermined display means is normal or not. It is possible to confirm the current set value by using the predetermined display means. This makes it possible to accurately confirm the set value. In addition, when the display for checking is being performed, the setting display state is set, and the display for checking is ended based on the operation of the predetermined operation means, and the current set value is displayed. This makes it possible to terminate the check display and display the current set value on the predetermined display means without waiting for the check display to be terminated when the settable status is reached. .. Therefore, it becomes possible to confirm the current set value at an early stage.

Furthermore, in the configuration in which the set value to be used is updated based on the operation of the predetermined operation means in the settable situation, the check display is displayed based on the operation of the predetermined operation means in the settable situation. Since the current setting value is displayed after the completion, the dedicated operation for terminating the check display and displaying the current setting value is not required. Therefore, it is possible to improve the workability of the work for updating the setting value to be used.

Feature d9. As the predetermined setting-related processing, there is provided means for executing processing for displaying the current setting value on the predetermined display means (function for executing setting confirmation processing in the main CPU 63). The gaming machine according to any one of the features d2 to d8.

According to the characteristic d9, not only the process for confirming the current set value but also the process for starting the check display on the predetermined display means can be integrated with the process at the start of the supply of the operating power. It will be possible.

Feature d10. The predetermined display control means is provided with means for displaying information corresponding to the management result of the game history on the predetermined display means (function of executing the processes of steps S8708, S8709 and S9107 in the main CPU 63). The gaming machine according to any one of the features d1 to d9.

According to the feature d10, it becomes possible to notify the manager of the game hall of the management result of the game history. In this case, whether or not the information corresponding to the management result of the game history on the predetermined display means is accurately displayed by providing the check display on the predetermined display means with the configuration of the characteristic d1. It becomes possible to confirm.

In addition, with respect to the configurations of the features d1 to d10, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, Any one or a plurality of configurations of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the inventions related to the characteristic c group and the characteristic d group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine such as the above example, a configuration capable of confirming whether or not the display on the predetermined display means is accurately performed is required, and there is still room for improvement in this respect. is there.

<Feature e group>
Feature e1. When a predetermined event occurs due to the execution of a game, history storage execution means (normal entrance management processing in the main CPU 63) for storing history information of the game corresponding to it in the history storage means (normal counter area 231) Function to execute)
Information derivation means (function of executing the process of step S8601 in the main CPU 63) for deriving mode information (base value) corresponding to the result of the game using the history information stored in the history storage means,
Mode information storage means (operation result storage area 234) for storing the mode information derived by the information derivation means,
Equipped with
A gaming machine characterized in that the aspect information storage means is capable of storing a plurality of the aspect information derived at different timings by the information deriving means.

According to the feature e1, when the predetermined event occurs, the history information corresponding to the predetermined event is stored in the history storage means. By storing the history information in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, the mode information corresponding to the result of the game is derived using the history information stored in the history storage means, and the derived mode information is stored in the mode information storage means. As a result, it becomes possible to store and hold information for managing the number of occurrences or the frequency of occurrence of a predetermined event in the gaming machine, and it is preferable to manage the frequency of occurrence of the predetermined event by using this managed information. It becomes possible to do it. Further, the aspect information storage means can store a plurality of aspect information derived at different timings. Accordingly, it is possible to grasp the frequency of occurrence of the predetermined event in a plurality of periods, so that it is possible to accurately grasp the frequency of occurrence of the predetermined event.

Feature e2. The aspect information storage means,
A latest storage area (current area 311) for storing the latest aspect information derived by the information deriving means;
And a past storage area (first to third history areas 312 to 314) that stores the aspect information derived by the information deriving unit before the aspect information stored in the latest storage area. The gaming machine described in the feature e1.

According to the feature e2, each of the latest aspect information and the past aspect information derived before that is stored, so that not only the latest frequency of occurrence of the predetermined event but also the past frequency is grasped. It becomes possible.

Feature e3. A period elapse identifying unit that identifies that a predetermined period has elapsed from the occurrence of the period start trigger to the occurrence of the period end trigger (a function of the main CPU 63 that executes the processes of steps S8605 and S8613);
Nearest memory execution means (step in the main CPU 63) for storing the aspect information derived by the information deriving means in the nearest memory area in a situation where the predetermined period has not been specified by the period elapsed specifying means. Function for executing the process of S8602),
Based on the fact that the predetermined period has been specified by the period elapse specifying unit, the predetermined value derived by the information deriving unit using the history information stored in the history storage unit Past memory execution means (a function of executing the processing of steps S8607 and S8614 in the main CPU 63) for storing the period corresponding mode information corresponding to the result of the game in the period in the past memory area,
The gaming machine according to feature e2, which is provided with

According to the feature e3, the aspect information derived when the predetermined period has not elapsed is stored in the latest storage area, and the aspect information derived when the predetermined period has elapsed is stored in the past storage area. To be done. As a result, it is possible to grasp the latest occurrence frequency of the predetermined event and also to grasp the past occurrence frequency of the predetermined event in units of a predetermined period. Further, since the form information in units of a predetermined period is stored in the past storage area, the number of form information stored in the past storage area can be suppressed.

Feature e4. Means for erasing the history information stored in the history storage means based on the fact that the predetermined period has been specified by the period elapsed specification means (processing of steps S8608 and S8615 in the main CPU 63) The game machine according to feature e3, which is provided with a function of executing

According to the feature e4, since the history information in the history information storage means is erased when a predetermined period has elapsed, it is possible to suppress the storage capacity required in the history information storage means. Further, even if the history information is erased after the predetermined period elapses in this manner, the mode information derived by using the history information in the predetermined period is stored in the past storage area. It is possible to later grasp the frequency of occurrence of the predetermined event during the period.

Feature e5. The gaming machine according to any one of features e2 to e4, wherein the past storage area can store a plurality of pieces of the aspect information having different derived timings.

According to the feature e5, since a plurality of pieces of aspect information are stored in the past storage area, it is possible to compare the occurrence frequencies of predetermined events corresponding to a plurality of periods.

Feature e6. A period elapse specifying unit that specifies that a predetermined period has elapsed from the occurrence of the predetermined period start trigger to the occurrence of the predetermined period end trigger (function of executing the processes of steps S8605 and S8613 in the main CPU 63) )When,
The predetermined period derived by the information deriving unit using the history information stored in the history storage unit based on the fact that the predetermined period has been identified by the period lapse identifying unit. Past memory execution means (a function of executing the processing of steps S8607 and S8614 in the main CPU 63) for storing the mode information corresponding to the period corresponding to the result of the game in the period in the mode information storage means,
Equipped with
The game according to any one of the features e1 to e5, wherein the mode information storage means is capable of storing a plurality of mode information corresponding to the respective periods corresponding to different predetermined periods. Machine.

According to the feature e6, since a plurality of past aspect information derived in units of a predetermined period is stored, it is possible to support a plurality of periods while suppressing the number of aspect information stored in the aspect information storage means. It becomes possible to compare the frequency of occurrence of the predetermined event.

Feature e7. Means for erasing the history information stored in the history storage means based on the fact that the predetermined period has been specified by the period elapsed specification means (processing of steps S8608 and S8615 in the main CPU 63) The game machine according to feature e6, which is provided with a function for executing.

According to the characteristic e7, since the history information in the history information storage means is erased when a predetermined period has elapsed, it becomes possible to suppress the storage capacity required in the history information storage means. Further, even if the history information is erased after the predetermined period elapses in this manner, the mode information derived by using the history information in the predetermined period is stored in the past storage area. It is possible to later grasp the frequency of occurrence of the predetermined event during the period.

Feature e8. Means (main side) for controlling the notification means (first to fourth notification display devices 201 to 204) so that the notifications corresponding to each of the plurality of mode information stored in the mode information storage means are sequentially executed The gaming machine according to any one of features e1 to e7, which is provided with a function of executing the processing of steps S8702 to S8709 in the CPU 63.

According to the characteristic e8, the notification corresponding to the mode information is performed by the notification means. This makes it possible to grasp the frequency of occurrence of the predetermined event. Further, since the notification corresponding to each of the plurality of aspect information is sequentially executed, it is possible to individually grasp the occurrence frequency of the predetermined event in a plurality of periods while suppressing the number of notification means.

Feature e9. The aspect information storage means includes a first storage area (first history area 312) capable of storing the aspect information and a second storage area (second history area 313) capable of storing the aspect information. ) And,
The gaming machine shifts the aspect information stored in the first storage area to the second storage area by an instruction including at least an LDIR instruction when an information shift trigger occurs (step S8607 in the main CPU 63). And the function of executing the process of step S8614), The gaming machine according to any one of features e1 to e8.

According to the feature e9, it is possible to shift between the storage areas of the mode information with a simple processing configuration.

In addition, with respect to the configurations of the features e1 to e9, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the above-mentioned characteristic e group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, in a pachinko machine, the game machine front face section is provided with a dish storage section for storing the game balls given to the player, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, it is necessary to manage the gaming machine appropriately, and there is still room for improvement in this respect.

<Feature f group>
Feature f1. Means for executing processing at the start of supply of operation power based on start of supply of operation power (in the thirty-fifth embodiment, a function of executing the processing of steps S8801 to S8819 in the main CPU 63, the thirty-sixth embodiment). In the embodiment, a function of executing the processing of steps S9401 to S9420 in the main CPU 63),
A power failure monitoring means for performing a power failure monitoring process for monitoring the occurrence of a power failure in a situation where the process at the time of starting the supply of the operating power is being performed (a function of executing the process of step S8901 in the main CPU 63). )When,
A gaming machine characterized by being equipped with.

According to the characteristic f1, since the power failure monitoring processing is executed even in the situation where the processing at the start of the supply of the operating power is executed, the power failure occurs in the situation where the processing at the start of the supply of the operating power is executed. When it occurs, it can be dealt with appropriately.

Feature f2. A means for executing an interrupt process that is regularly activated (a function for executing a first timer interrupt process in the main CPU 63),
The interruption processing includes the power failure monitoring processing,
The gaming machine according to feature f1, wherein the interrupt process can be interrupted and activated in a situation where the process at the start of supplying the operating power is being executed.

According to the feature f2, even when the process at the start of supplying the operating power is being executed, the interrupt process is periodically interrupted and activated, so that the process at the start of supplying the operating power is executed. Even in the situation, it becomes possible to regularly monitor the occurrence of power failure.

Feature f3. The interrupt processing can be activated in an interrupted manner even in a situation where post-end processing (steps S8822 to S8825 in the main CPU 63) is being executed after the processing at the start of supplying the operating power is completed. The gaming machine according to feature f2.

According to the feature f3, interruption processing that can be activated by interruption in a situation where post-completion processing is being executed is used to regularly monitor the occurrence of a power failure in a situation where processing at the start of supply of operating power is being executed. It becomes possible to do it.

Feature f4. The interrupt processing includes a progress corresponding process (step S8907 to step S8920 in the main CPU 63) executed to control the progress of the game,
When the interrupt processing is interrupted and activated in a situation where the processing at the start of supply of the operating power is executed, the power failure monitoring processing is executed, while the progress handling processing is not executed,
When the interrupt processing is interrupted and activated in a situation where the post-end processing is being executed, both the power failure monitoring processing and the progress handling processing can be executed, and the characteristic f3 is described. Game machine.

According to the feature f4, the interrupt process that can be interrupted and activated in the situation where the post-termination process is being executed is used to regularly monitor the occurrence of the power outage in the situation where the process at the start of supplying the operating power is being executed. In a configuration to be performed in a general manner, even if the interrupt process is interrupted and activated in the situation where the process at the time of starting the supply of the operating power is being executed, the progress corresponding process for controlling the progress of the game is not executed. It becomes possible to do.

Feature f5. A setting means (a function of executing a set value update process in the main CPU 63) for setting a set value to be used from a plurality of set values corresponding to the player's advantage is provided.
Any one of features f1 to f4, which can be a settable state in which the setting value to be used can be changed in a situation where the process at the start of supplying the operating power is being executed. Gaming machine described in.

According to the feature f5, the power failure monitoring process is executed even in the situation where the setting value to be used is set, so a power failure occurs during the setting of the setting value to be used. Even if it does, it is possible to deal with it appropriately.

Feature f6. If the supply of operating power is stopped after the occurrence of a power failure is identified in the power outage monitoring process, and if the supply of operating power is restarted, it is set as a target for use before the supply of operating power is stopped. The game machine according to feature f5, wherein the game can be played with the set value set.

According to the feature f6, even if a power failure occurs in the situation where the setting value to be used is set, the occurrence of the power failure is identified by the power failure monitoring process, so that the supply of operating power is restarted. In this case, it becomes possible to play the game in the situation where the set value selected at the timing of the power failure is the target of use. As a result, even if a power failure occurs in the situation where the setting value to be used is being set, there is no need to set the setting value again when the supply of operating power is resumed.

In addition, with respect to the configurations of the features f1 to f6, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the characteristic f group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, in a pachinko machine, the game machine front face section is provided with a dish storage section for storing the game balls given to the player, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, it is necessary to appropriately deal with the occurrence of a power outage in the gaming machine as illustrated above, and there is still room for improvement in this respect.

<Characteristic group g>
Feature g1. Setting correspondence storage areas (first to sixth setting information storages in the thirty-ninth embodiment) for storing setting correspondence information (low probability mode win/loss table, high probability mode win/loss table) corresponding to the advantage of the player Areas 325a to 325f, in the 40th embodiment, first to third setting information storage areas 326a to 326c), a setting correspondence storage means having a plurality of first predetermined numbers (setting correspondence storage area 325 in the 39th embodiment, In the 40th embodiment, a setting correspondence storage area 326),
Setting means for setting a set value to be used (a function for executing a set value updating process in the main CPU 63);
Using the setting correspondence information stored in the setting correspondence storage area corresponding to the setting value set by the setting unit, a profit related unit for executing a profit related process (step S504) related to a player's profit. (Function of executing special figure variation start processing in the main CPU 63),
Equipped with
A game machine characterized in that the number of kinds of the set values that can be set by the setting means is smaller than the first predetermined number.

According to the characteristic g1, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player can use the more advantageous setting value as the usage target. Will be expected. In this case, in the configuration in which the first predetermined number of setting correspondence storage areas for storing the setting correspondence information corresponding to the setting values are provided, the number of kinds of setting values to be used is smaller than the first predetermined number. It is a small number. As a result, the configuration relating to the setting correspondence storage means can be shared with the gaming machine in which the number of types of setting values to be used is the first predetermined number, and the gaming machine in the case of changing the number of types of setting values can be used. The design work can be performed easily. From the above, it is possible to make the configuration related to the set value suitable.

Feature g2. And a correspondence information storage unit (setting value counter in the specific control work area 221) capable of storing and holding correspondence information corresponding to each of the first predetermined number of the setting correspondence storage areas,
The setting means sets the setting value to be used by changing the correspondence information stored and held in the correspondence information storage means based on a change operation,
The setting correspondence information of the setting values that can be set by the setting means is stored in at least one of the setting correspondence storage areas, and is a part of the first predetermined number and corresponds to a plurality of the setting correspondences. Since the same setting correspondence information is stored in the storage area, the setting correspondence information is stored in all of the first predetermined number of the setting correspondence storage areas. The gaming machine described in g1.

According to the feature g2, the setting value to be used is changed by changing the correspondence information stored and held in the correspondence information storage means based on the changing operation, and the setting correspondence storage area corresponding to the changed correspondence information. By using the setting correspondence information of (1) in the profit-related processing, the profit-related processing is executed in a mode corresponding to the setting value of the usage target. In this case, the setting correspondence information of the setting values that can be set by the setting means is stored in at least one setting correspondence storage area, and is a part of the first predetermined number, and is a plurality of setting correspondence storages. Since the same setting correspondence information is stored in the area, the setting correspondence information is stored in all of the first predetermined number of setting correspondence storage areas. Thus, the first predetermined number of setting correspondence storage areas are used as they are, and the configuration for determining the setting value to be used by using the correspondence information storage means is used as it is, while the number of kinds of setting values to be used is Can be smaller than the first predetermined number.

Feature g3. The profit-related means is
A means for reading the setting correspondence information from the setting correspondence storage area corresponding to the correspondence information stored and held in the correspondence information storage means (a function for executing the read/write processing of the hit/miss table in the main CPU 63);
Means for executing the profit-related processing by utilizing the read setting correspondence information (function for executing the processing of step S504 in the main CPU 63);
The gaming machine described in the feature g2, which is characterized by comprising:

According to the characteristic g3, even if the number of kinds of setting values to be used is smaller than the first predetermined number, the setting correspondence corresponding to the correspondence information stored and held in the correspondence information storage means is provided. Since the profit-related processing may be executed by using the setting correspondence information read from the storage area, the configuration for reading the setting correspondence information when executing the profit-related processing can be used as it is.

Feature g4. Predetermined display control for causing a predetermined display unit (fourth notification display device 204) to perform a display corresponding to the current set value in a situation where the correspondence information stored and held in the correspondence information storage unit can be changed. Means (function of executing the processing of steps S9801 to S9804 in the main CPU 63),
The predetermined display control means is
A means for reading out display information of the setting value corresponding to the setting correspondence information stored in the setting correspondence storage area corresponding to the correspondence information of the correspondence information storage means (processing of steps S9801 to S9803 in the main CPU 63). Function to execute)
Means for causing the predetermined display means to perform a display corresponding to the read display information of the set value (a function of the main CPU 63 for executing the processing of step S9804);
The gaming machine according to the feature g2 or g3, which is characterized by comprising:

According to the feature g4, when changing the setting value to be used, it is possible to perform the setting value changing operation while confirming the display corresponding to the current setting value displayed on the predetermined display means. Become. In this case, even if the number of types of setting values to be used is less than the first predetermined number, the setting correspondence information in the setting correspondence storage area corresponding to the correspondence information in the correspondence information storage means The display information of the corresponding set value is read out and a display corresponding to the read display information of the set value is displayed on a predetermined display means. As a result, the configuration for reading the display information of the set value can be used as it is when executing the display corresponding to the set value.

Feature g5. The number of kinds of the set values that can be set by the setting unit is a divisor of the first predetermined number and is a number different from the first predetermined number,
The gaming machine according to feature g4, wherein the number of the setting correspondence storage areas in which the setting correspondence information corresponding to each setting value is stored is the same among the setting values.

According to the feature g5, even if the number of kinds of set values to be used is smaller than the first predetermined number, the frequency with which the display corresponding to the set value is performed by the predetermined display means is determined. The set values can be the same.

Feature g6. The setting correspondence information corresponding to the same setting value is stored in the setting correspondence storage area corresponding to the correspondence information in a consecutive order in the change order of the correspondence information stored and held in the correspondence information storage means. The gaming machine described in the feature g4 or g5, which is characterized in that it is not present.

According to the feature g6, it is possible to change the set value to be displayed on the predetermined display means each time the changing operation is performed once. This makes it possible to improve the operability of the changing operation even if the number of types of setting values to be used is smaller than the first predetermined number.

In addition, with respect to the configuration of the features g1 to g6, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention relating to the above-mentioned characteristic g group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as exemplified above, it is necessary to make the configuration relating to the set value that determines the advantage of the gaming machine suitable, and there is still room for improvement in this respect.

<Feature h group>
Features h1. Display means (special figure display section 37a, special figure reservation display section 37b, general figure display section 38a, general figure reservation display section 38b, first to fourth notification display devices 201 to 204, first to fifth display circuit 261 ~265),
Display control means (main CPU 63) for transmitting display data (display data signal, display clock signal) corresponding to the display content to be displayed on the display means,
Display execution means (display IC 266) for performing display setting on the display means so that the display content corresponds to the display data when the display data is transmitted by the display control means,
In a gaming machine equipped with
A plurality of the display means,
The display control unit includes a sequential transmission unit (a function of executing a second timer interrupt process in the main CPU 63) that sequentially transmits the display data corresponding to each of the plurality of display units to the display execution unit,
The display execution means, when the display data is transmitted by the display control means, displays the display content corresponding to the display data to the display means to which the display data is set among the plurality of display means. The above display settings are made so that
The transmission interval of the display data from the sequential transmission means to the display execution means is such that the display execution means is provided to each display means before the display corresponding to the display data cannot be maintained in each display means. A game machine characterized in that the display interval is set according to the transmission interval.

According to the feature h1, the display execution means sets the display on the display means in accordance with the display data transmitted from the display control means, so that the display means is display-controlled so that the display content corresponds to the display data. It This makes it possible to reduce the processing load on the display control means. In this case, in the configuration in which the plurality of display means are provided, the display execution means is not provided in a one-to-one correspondence with the plurality of display means, but one display is provided for the plurality of display means. The execution means is also used. This makes it possible to increase the number of display means while suppressing the increase in the number of display execution means. Further, the transmission interval of the display data from the display control means to the display execution means is set to the display execution means by the display execution means before the display corresponding to the display data cannot be maintained in each display means. Is set to the transmission interval at which Accordingly, even in the configuration in which one display execution unit is also used for a plurality of display units, it is possible to appropriately perform the display corresponding to the display data on each display unit. As described above, it is possible to make the configuration for controlling the display of the display unit suitable.

Features h2. When the display data is transmitted to the display execution unit, the sequential transmission unit transmits the identifiable information (type data signal, type clock signal) that enables identification of the type of the display unit to which the display data is set. The gaming machine described in the characteristic item h1, which is transmitted to the display executing means.

According to the characteristic h2, when the display data is transmitted from the display control means, the display execution means may set the display data to the display means corresponding to the identifiable information transmitted from the display control means. This makes it possible to simplify the configuration of the display executing unit even if one display executing unit also serves as a plurality of display units.

Features h3. The sequential transmission means is configured to repeat the update cycle when the update cycle is set such that the plurality of display means are set once in the predetermined order as the display data setting target. The gaming machine according to the characteristic h1 or h2, characterized in that the display data is transmitted.

According to the characteristic h3, the display control means only needs to change the display means to which the display data is transmitted in accordance with a predetermined order, so that the processing configuration of the display control means can be simplified.

Features h4. Even if the content of the display data for one of the display units is the same as the content of the display data when the display unit was previously transmitted as the transmission target, the sequential transmission unit determines that the display unit is the transmission target. The gaming machine described in any one of the features h1 to h3, characterized in that the display data is transmitted when the gaming data is lost.

According to the characteristic h4, since the display data is transmitted even if the content of the display data to be transmitted is not changed, one display executing means is also used for a plurality of display means. Also, the same display can be continued by a predetermined display means.

Features h5. The sequential transmission unit executes a process for transmitting the display data by a predetermined interrupt process (second timer interrupt process) which is activated by being interrupted when the display control unit is executing a predetermined process. The gaming machine according to any one of features h1 to h4.

According to the characteristic h5, since the processing for transmitting the display data is executed by the predetermined interrupt processing, it is possible to set the cycle in which the display data is set in each display means to the predetermined cycle. Therefore, even in a configuration in which one display execution means is also used for a plurality of display means, before each display means cannot maintain the display corresponding to the display data, It is possible to set the display data by the display executing means.

Features h6. The processing for transmitting the display data by the display executing means to the plurality of display means to be subjected to the display setting is integrated into the predetermined interrupt processing. Amusement machine.

According to the feature h6, it is possible to set the cycle in which the display data is set by the display execution means to each display means that is the target of the display setting to be the same cycle.

Features h7. The display control unit includes a unit (a function of executing the first timer interrupt process in the main CPU 63) that interrupts and activates a specific interrupt process (first timer interrupt process) in a state where the predetermined process is being executed. ,
The gaming machine according to the characteristic h5 or h6, wherein the interrupt cycle of the predetermined interrupt processing is shorter than the interrupt cycle of the specific interrupt processing.

According to the characteristic h7, the process of transmitting the display data to the display executing means is executed in the predetermined interrupt process which is shorter than the interrupt period of the specific interrupt process. As a result, the display data can be transmitted in a shorter cycle than the configuration in which the process of transmitting the display data to the display executing means is executed in the specific interrupt process.

Feature h8. The gaming machine according to feature h7, wherein a process for advancing a game is executed in the specific interrupt process.

According to the characteristic h8, it is possible to achieve the excellent effect as already described while activating the specific interrupt process at an appropriate cycle in executing the process for advancing the game.

Features h9. The gaming machine according to feature h7 or h8, wherein the predetermined interrupt process is interrupted and activated even when the specific interrupt process is being executed.

According to the characteristic h9, the predetermined interrupt processing is interrupted and activated even in the situation where the specific interrupt processing is being executed. Therefore, even if the specific interrupt processing is activated by the interrupt, the transmission cycle of the display data is reduced. It becomes possible to set a predetermined cycle.

Features h10. Features h7 to h9 characterized in that the interrupt of the specific interrupt process is prohibited when the predetermined interrupt process is started, and the interrupt of the specific interrupt process is permitted when the predetermined interrupt process is terminated. The gaming machine according to any one of the above.

According to the characteristic h10, it is possible to prevent the specific interrupt processing from being interrupted and executed in the situation where the predetermined interrupt processing is being executed. This makes it possible to prioritize the processing for transmitting the display data.

Features h11. The display control unit is a unit that executes a process at the time of starting the supply of the operating power when the supply of the operating power is started (in the 33rd embodiment, a function of executing the processes of steps S7901 to S7918 in the main CPU 63). The function of executing the processing of steps S8801 to S8819 in the main CPU 63 in the 35th embodiment, the function of executing the processing of steps S9401 to S9420 in the main CPU 63 in the 36th embodiment, the 37th embodiment. A function of executing the processing of steps S9501 to S9518 in the main CPU 63, and a function of executing the processing of steps S9901 to S9917 in the main CPU 63 in the 42nd embodiment).
The gaming machine according to any one of features h5 to h10, wherein the predetermined interrupt process is activated by interrupting even when the process at the time of starting the supply of the operating power is being executed.

According to the characteristic h11, it is possible to control the display of the plurality of display units even in the situation where the process at the start of supplying the operating power is being executed. Further, since the predetermined interrupt process is activated by interrupting the process at the start of the supply of the operating power, the supply of the operating power can be performed without complicating the process configuration of the process at the start of supplying the operating power. It is possible to control the display of a plurality of display means in a situation where the processing at the start is being executed.

Features h12. A setting means (a function of executing a set value update process in the main CPU 63) for setting a set value to be used from a plurality of set values corresponding to the player's advantage is provided.
In a situation where the process at the time of starting the supply of the operating power is being executed, it is a configuration that can be a settable situation in which the setting value to be used can be changed,
The sequential transmission means transmits the display data to the display execution means so that a display corresponding to the current set value is displayed on the predetermined display means in the setting possible state. The gaming machine described in feature h11.

According to the characteristic h12, since the current setting value is displayed on the predetermined display means in the situation where the setting value to be used is set, it becomes easy to perform the setting work of the setting value to be used. ..

Features h13. The display control means includes means (function of executing first timer interrupt processing in the main CPU 63) for executing progress corresponding processing for controlling the progress of the game after the processing at the start of supply of the operating power is completed. Prepare,
The sequential transmission means sends the display data to the display execution means so that the correspondence display corresponding to the execution result of the progress correspondence processing is displayed on at least a part of the display means. To send,
The gaming machine according to feature h11 or h12, wherein the predetermined interrupt process is interrupted and activated even after the process at the start of supplying the operating power is completed.

According to the characteristic h13, by using the predetermined interrupt process, it is possible to perform a plurality of processes in both the situation in which the process at the start of supplying the operating power is being executed and the situation after the process at the start of supplying the operating power is completed. It becomes possible to control the display of the display means.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features h1 to h13. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, Any one or a plurality of configurations of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature i group>
Feature i1. First interrupt executing means (first timer interrupt process in the main CPU 63) that interrupts the other process and executes the first interrupt process based on the lapse of the first interrupt cycle in a state where the other process is being executed. Function to execute)
Second interrupt execution means (second timer interrupt process in the main CPU 63) that interrupts the other process and executes the second interrupt process based on the lapse of the second interrupt cycle in the state where the other process is being executed. Function to execute)
Equipped with
The second interrupt cycle is shorter than the first interrupt cycle,
For controlling the display of predetermined display means (special figure display section 37a, special figure reservation display section 37b, general figure display section 38a, general figure reservation display section 38b, first to fourth display devices 201 to 204). A game machine, wherein the processing is executed by the second interrupt processing.

According to the feature i1, the process for controlling the display of the predetermined display means is executed by the predetermined interrupt process which is a period shorter than the interrupt period of the specific interrupt process. As a result, the display control of the predetermined display unit can be performed in a shorter cycle than the configuration in which the process for controlling the display of the predetermined display unit is executed in the specific interrupt process.

Feature i2. The game machine according to the feature i1, wherein a process for advancing a game is executed in the first interrupt process.

According to the feature i2, the first interrupt process is activated at an appropriate cycle for executing the process for advancing the game, and it is possible to obtain the excellent effect as already described.

Feature i3. The gaming machine according to feature i1 or i2, wherein the second interrupt process is activated by interrupting even when the first interrupt process is being executed.

According to the feature i3, the second interrupt processing is interrupted and activated even in the situation where the first interrupt processing is being executed. Therefore, even if the first interrupt processing is activated by interruption, the predetermined display The display control of the means can be performed at a predetermined cycle.

Feature i4. The interrupt of the first interrupt process is prohibited when the second interrupt process is started, and the interrupt of the first interrupt process is permitted when the second interrupt process is ended. The gaming machine according to any one of i1 to i3.

According to the feature i4, it is possible to prevent the first interrupt process from being interrupted and executed in the situation where the second interrupt process is being executed. This makes it possible to give priority to the display control of the predetermined display means.

Feature i5. A means (a function for executing a main process in the main CPU 63) for executing a process at the time of starting the supply of the operating power when the supply of the operating power is started,
The gaming machine according to any one of features i1 to i4, wherein the second interrupt process is activated by being interrupted even in a situation where the process at the start of supplying the operating power is being executed.

According to the feature i5, it is possible to control the display of a predetermined display unit even in the situation where the process at the start of supplying the operating power is being executed. In addition, since the second interrupt process is configured to be activated by interrupting the process at the start of the supply of the operating power, the operation power can be supplied without complicating the process configuration of the process at the start of supplying the operating power. It is possible to display-control a predetermined display unit in a situation where the process at the start of supply is being executed.

Feature i6. A setting means (a function of executing a set value update process in the main CPU 63) for setting a set value to be used from a plurality of set values corresponding to the player's advantage is provided.
In a situation where the process at the time of starting the supply of the operating power is being executed, it is a configuration that can be a settable situation in which the setting value to be used can be changed,
The second interrupt execution means executes, in the second interrupt processing, processing for causing the display corresponding to the current set value to be displayed on the predetermined display means in the settable status. The gaming machine according to feature i5.

According to the feature i6, since the current setting value is displayed on the predetermined display means in the situation where the setting value to be used is set, it becomes easy to perform the setting operation of the setting value to be used. ..

Feature i7. The second interrupt execution means executes the second interrupt processing based on the lapse of the second interrupt cycle even after the processing at the start of supplying the operating power is completed, i5 Alternatively, the gaming machine described in i6.

According to the feature i7, by using the predetermined interrupt process, the predetermined process is performed in both the situation in which the process at the start of the supply of the operating power is being executed and the situation after the process at the start of the supply of the operating power is completed. It becomes possible to control the display of the display means.

In addition, with respect to the configurations of the features i1 to i7, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the inventions related to the characteristic h group and the characteristic i group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as exemplified above, it is necessary to make the structure for displaying by the display means suitable, and there is still room for improvement in this respect.

<Feature j group>
Feature j1. Means for executing processing at the start of supply of operation power based on start of supply of operation power (in the 33rd embodiment, a function of executing the processing of steps S7901 to S7918 in the main CPU 63, the 35th embodiment). In the embodiment, the function of executing the processing of steps S8801 to S8819 in the main CPU 63, in the 36th embodiment, the function of executing the processing of steps S9401 to S9420 in the main CPU 63, and in the 37th embodiment, the main CPU 63 A function of executing the processing of steps S9501 to S9518 in the above, and a function of executing the processing of steps S9901 to S9917 in the main CPU 63 in the 42nd embodiment).
Predetermined interrupt executing means for interrupting the process at the start of supplying the operating power and executing a predetermined interrupt process (a function for executing a first timer interrupt process in the main CPU 63, a function for executing a second timer interrupt process in the main CPU 63) )When,
A gaming machine characterized by being equipped with.

According to the feature j1, since the predetermined interrupt process is activated by interruption even in the situation where the process at the start of the supply of the operating power is being executed, the predetermined interrupt process is set even immediately after the start of the supply of the operating power. It is possible to give priority to the execution of the processing that is being performed. Further, since it is not necessary to set the process set as the predetermined interrupt process with respect to the process at the time of starting the supply of the operating power, the operation can be performed without complicating the processing configuration of the process at the start of supplying the operating power. Even immediately after the start of power supply, it is possible to give priority to the execution of the process set as the predetermined interrupt process. As described above, it is possible to preferably perform the processing when the supply of the operating power is started.

Feature j2. The predetermined interrupt executing means is a predetermined display means (special figure display section 37a, special figure reservation display section 37b, general figure display section 38a, general figure reservation display section 38b, first to fourth notification display devices 201 to 204. ) The process for controlling the display is executed by the predetermined interrupt process, the gaming machine according to the feature j1.

According to the feature j2, it is possible to display a predetermined display on a predetermined display means even immediately after the start of supplying the operating power.

Feature j3. A setting means (a function of executing a set value update process in the main CPU 63) for setting a set value to be used from a plurality of set values corresponding to the player's advantage is provided.
In a situation where the process at the time of starting the supply of the operating power is being executed, it is a configuration that can be a settable situation in which the setting value to be used can be changed,
The predetermined interrupt execution means performs a process for causing the predetermined display means (fourth notification display device 204) to display a display corresponding to the current set value in the settable status in the predetermined interrupt processing. The gaming machine according to the feature j1 or j2, which is characterized by being executed as follows.

According to the feature j3, since the current setting value is displayed on the predetermined display means in the situation where the setting value to be used is set, it becomes easy to perform the setting work of the setting value to be used. ..

Feature j4. One of the features j1 to j3, wherein the predetermined interrupt execution means executes the predetermined interrupt processing based on the lapse of a predetermined interrupt cycle even after the processing at the start of supplying the operating power is completed. The gaming machine described in 1.

According to the feature j4, by using the predetermined interruption process, the predetermined process is performed in both the situation where the process at the start of the supply of the operating power is being executed and the situation after the process at the start of the supply of the operating power is completed. It is possible to execute the process set as the interrupt process.

Feature j5. The gaming machine according to any one of features j1 to j4, wherein the predetermined interrupt executing means executes a power failure monitoring process (step S8901) for monitoring occurrence of a power failure by the predetermined interrupt process.

According to the feature j5, the power failure monitoring processing is executed even in the situation where the processing at the start of the supply of the operating power is executed, so that the power failure occurs in the situation where the processing at the start of the supply of the operating power is executed. When it occurs, it can be dealt with appropriately.

Feature j6. The predetermined interruption process includes a progress corresponding process (steps S8907 to S8920 in the main CPU 63) executed to control the progress of the game,
When the predetermined interrupt process is interrupted and activated in a situation where the process at the start of the supply of the operating power is being executed, the power failure monitoring process is executed while the progress handling process is not executed,
When the predetermined interrupt processing is interrupted and activated in a situation where post-termination processing (step S8822 to step S8825 in the main CPU 63) is executed after the processing at the start of supplying the operating power is completed, the power failure monitoring is performed. The gaming machine according to feature j5, wherein both the processing and the progress corresponding processing can be executed.

According to the feature j6, the occurrence of a power failure is monitored in the situation where the processing at the start of the supply of the operating power is being performed by using the predetermined interrupt processing that can be interrupted and activated in the situation where the post-termination processing is being executed. In the configuration that is performed periodically, even if the predetermined interrupt process is interrupted and activated in the situation where the process at the time of starting the supply of the operating power is being executed, the progress corresponding process for controlling the progress of the game is not executed. It becomes possible to do so.

For the configurations of the features j1 to j6, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the above-mentioned characteristic j group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, it is necessary to suitably perform the processing when the supply of the operating power is started, and there is still room for improvement in this respect.

<Characteristic k group>
Features k1. When a predetermined event occurs due to the execution of a game, history storage execution means (normal entrance management processing in the main CPU 63) for storing history information of the game corresponding to it in the history storage means (normal counter area 231) Function to execute)
Information derivation means (a function of executing the process of step SA201 in the main CPU 63) for deriving mode information (base value) corresponding to the result of the game using the history information stored in the history storage means,
Mode information display control means (main CPU 63) for controlling the display of the information display means (first to fourth notification display devices 201 to 204) so that the display corresponding to the mode information derived by the information deriving means is performed. Function for executing display processing and second timer interrupt processing in)
A predetermined correspondence display (pre-shift display) is performed on the information display means before a display corresponding to the aspect information is newly started based on occurrence of a predetermined display trigger. Control means (function of executing the processing of step SA320 and the second timer interrupt processing in the main CPU 63);
A gaming machine characterized by being equipped with.

According to the characteristic k1, when the predetermined event occurs, the history information corresponding to the predetermined event is stored in the history storage means. By storing the history information in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, the mode information corresponding to the result of the game is derived by using the history information stored in the history storage means, and the information display means performs the display corresponding to the derived mode information. Thereby, it becomes possible to grasp the management result of the game history such as the frequency of occurrence of the predetermined event. Further, the predetermined corresponding display is performed by the information display means before the display corresponding to the aspect information is newly started based on the occurrence of the predetermined display trigger. With this, when a predetermined display trigger is generated, the predetermined corresponding display corresponding thereto can be preferentially displayed on the information display means over the display corresponding to the aspect information, and the information display means can be used. It is possible to notify that a predetermined display trigger has occurred.

Feature k2. A period elapse specifying unit (function of executing the process of step SA210 in the main CPU 63) that specifies that a predetermined period has elapsed from the occurrence of the predetermined period start trigger to the occurrence of the predetermined period end trigger ,
The predetermined correspondence display control means is configured to display the predetermined correspondence display on the information display means on the assumption that the predetermined display trigger has occurred when the predetermined period has been specified by the period elapse specifying means. The gaming machine described in the feature k1 characterized by being performed.

According to the characteristic k2, when the predetermined period of time has elapsed, the information display means performs the predetermined correspondence display, and then the information display means newly starts the display corresponding to the aspect information. This allows the manager of the game hall to recognize that the mode information displayed on the information display means is after the lapse of a predetermined period.

Features k3. The information deriving unit uses the history information corresponding to the predetermined event that occurs after the predetermined period based on the fact that the predetermined period has been specified by the period lapse specifying unit. To derive the aspect information,
The predetermined correspondence display control means, based on the fact that the predetermined period has been specified by the period elapse specifying means, displays the history information corresponding to the predetermined event that occurs after the predetermined period. It is characterized in that the predetermined correspondence display is performed on the information display means before the display corresponding to the aspect information derived by the information deriving means is performed on the information display means. The gaming machine described in the feature k2.

According to the characteristic k3, in the configuration in which the mode information is newly derived on the basis of the passage of the predetermined period, after the predetermined period has elapsed, the predetermined display is performed by the information display means. A display corresponding to the newly derived mode information is performed after a lapse of a predetermined period. Thereby, the manager of the game hall can grasp whether or not the display corresponding to the mode information on the information display means is the display corresponding to the newly derived mode information after a predetermined period has elapsed. Becomes

Features k4. Means for erasing the history information stored in the history storage means based on the fact that the predetermined duration has been identified by the duration elapsed identification means (the processing of step SA217 in the main CPU 63 is executed). The gaming machine according to feature k3, which is provided with a function).

According to the characteristic k4, since the history information in the history information storage means is erased when a predetermined period has elapsed, it is possible to suppress the storage capacity required in the history information storage means.

Feature k5. Based on the fact that the predetermined period has been specified by the period elapse specifying means, the predetermined value derived by the information deriving means using the history information stored in the history storage means. A function for executing the processing of step SA203 and step SA216 in the main CPU 63 that stores the mode information corresponding to the result of the game in the period in the mode information storage unit (calculation result storage area 234) as the period corresponding mode information. ),
The aspect information display control means controls the display of the information display means so that a display corresponding to the period corresponding aspect information stored in the aspect information storage means is performed.
The predetermined correspondence display control means, based on the fact that the predetermined time period has been specified by the period elapse specification means, corresponds to the period newly stored in the aspect information storage means by the storage execution means. The game according to any one of features k2 to k4, characterized in that the predetermined correspondence display is performed on the information display means before the display corresponding to the aspect information is performed on the information display means. Machine.

According to the characteristic k5, the past aspect information derived in units of a predetermined period is stored as the period corresponding aspect information, and the information corresponding to the period corresponding aspect information is displayed on the information display means. Thereby, the manager of the game hall can grasp the past period corresponding mode information derived in units of a predetermined period by checking the information display means. Further, when the predetermined period has elapsed, after the predetermined correspondence display is performed by the information display means, the display corresponding to the period correspondence mode information newly derived as the predetermined period has elapsed is performed. Thereby, whether the display corresponding to the period corresponding mode information on the information display means is the display corresponding to the period corresponding mode information newly derived based on the lapse of a predetermined period is determined by the manager of the game hall. Can be grasped.

Features k6. The aspect information storage means is capable of storing a plurality of the period corresponding aspect information corresponding to each of the different predetermined periods,
The aspect information display control means controls the display of the information display means so that a display corresponding to each of the plurality of period corresponding aspect information stored in the aspect information storage means is performed. The gaming machine according to feature k5.

According to the feature k6, since a plurality of past period corresponding aspect information derived in units of a predetermined period are stored and a display corresponding to the plurality of period corresponding aspect information is performed by the information display means, a plurality of items are displayed. It is possible to compare the occurrence frequency of a predetermined event corresponding to a predetermined period.

Features k7. From the situation in which the display corresponding to the mode information is being performed, the information display means is set to the pre-switching state (state of non-display for interval) before displaying the mode information different from the mode information. The gaming machine according to any one of features k1 to k6, which is provided with a means (a function of executing the process of step SA316 and the second timer interrupt process in the main CPU 63).

According to the characteristic k7, when the mode information to be displayed is switched, the information display means is in the pre-switching state, so that the manager of the game hall clearly indicates that the mode information to be displayed has been switched. It becomes possible to grasp. In this case, the information display means provides the predetermined correspondence display on the basis of the occurrence of the predetermined display trigger, which is provided with the configuration of the characteristic k1. With this, it is possible to notify that a predetermined display trigger has occurred by using the information display unit that displays information corresponding to different mode information with the pre-switching state in between.

Feature k8. The predetermined correspondence display control means, when the predetermined display trigger occurs, the predetermined correspondence display is displayed on the information display means even if the display continuation period of the display corresponding to the aspect information has not elapsed. The gaming machine according to any one of the features k1 to k7, characterized in that the gaming machine is started.

According to the characteristic k8, when the predetermined display trigger is generated, the predetermined correspondence display is started even if the display corresponding to the aspect information is being performed. As a result, it is possible to promptly notify that a predetermined display trigger has occurred.

Feature k9. If the predetermined display trigger occurs in the middle of the display continuation period of the display corresponding to the aspect information, the predetermined correspondence display control means displays the predetermined correspondence display on the information display means after the display continuation period has elapsed. The gaming machine according to any one of the features k1 to k7, characterized in that the gaming machine is started.

According to the characteristic k9, even if a predetermined display trigger occurs, the predetermined correspondence display is started after the display corresponding to the mode information displayed at that time is completed. As a result, it is possible to notify that a predetermined display trigger has occurred while not disturbing the display corresponding to the mode information that has already been performed.

Feature k10. A mode information storage unit (operation result storage area 234) for storing the mode information derived by the information derivation unit is provided,
The aspect information storage means stores a plurality of specific storage areas (current area 311 and first history area 312) so as to be able to store each of the plurality of aspect information derived at different timings by the information deriving means. , A second history area 313, a third history area 314),
The aspect information display control means controls the information display means so that a display corresponding to each of the plurality of aspect information stored in the plurality of specific storage areas is sequentially executed according to a predetermined display order. The gaming machine according to any one of features k1 to k9.

According to the characteristic k10, since the notification corresponding to each of the plurality of aspect information is sequentially executed, it is possible to individually grasp the occurrence frequency of the predetermined event in a plurality of periods while suppressing the number of information display means. Becomes Further, since the display corresponding to each of the plurality of mode information stored in the plurality of specific storage areas is sequentially executed in accordance with the predetermined display order, the manager of the game hall grasps the type of mode information to be displayed. Easier to do.

Feature k11. The gaming machine according to feature k10, wherein a predetermined display order is defined in association with the plurality of specific storage areas.

According to the feature k11, since the predetermined display order of the display corresponding to the aspect information is determined in association with the plurality of specific storage areas, the display target is set when the display corresponding to one aspect information is newly started. It is possible to simplify the processing configuration for specifying the type of the aspect information.

Features k12. When the aspect information display control means causes the information display means to perform the display corresponding to the aspect information after the predetermined corresponding display is performed by the information display means, the aspect information display control means performs the first order in the predetermined display order. The gaming machine according to feature k10 or k11, which is started from a display corresponding to the corresponding aspect information.

According to the feature k12, after the predetermined correspondence display is performed based on the occurrence of the predetermined display trigger, the display corresponding to the mode corresponding to the first order in the predetermined display order is started. Accordingly, when a predetermined display trigger occurs, it is possible to confirm the display corresponding to the aspect information again from the first order in the predetermined display order.

Features k13. A period elapse specifying unit (a function of executing the process of step SA210 in the main CPU 63) that specifies that a predetermined period has elapsed from the occurrence of the predetermined period start trigger to the occurrence of the predetermined period end trigger;
The predetermined period derived by the information deriving unit using the history information stored in the history storage unit based on the fact that the predetermined period has been identified by the period lapse identifying unit. Storage execution means for storing the mode information corresponding to the result of the game in the period as the period-corresponding mode information in the plurality of specific storage areas (function of executing the processes of step SA203 and step SA216 in the main CPU 63),
Equipped with
Any one of the characteristics k10 to k12, characterized in that the storage execution means causes the period corresponding mode information to be stored in the plurality of specific storage areas in the order derived by the information derivation means. The gaming machine described in 1.

According to the characteristic k13, it becomes possible to confirm the period corresponding mode information according to the derived order.

Features k14. The information derivation means performs an information derivation process for deriving the aspect information based on the occurrence of a process execution trigger, and derives the aspect information after starting the derivation of the aspect information. The game machine according to any one of the features k1 to k13, wherein the information derivation process is executed a plurality of times until the completion of the above.

According to the feature k14, since the information derivation process is executed a plurality of times from the start of derivation of the mode information until the derivation of the mode information is completed, the derivation of the mode information is completed in one information derivation process. It is possible to reduce the processing load for executing the information derivation process compared to the configuration in which it is performed.

Feature k15. A period elapse specifying unit (a function of executing the process of step SA210 in the main CPU 63) that specifies that a predetermined period has elapsed from the occurrence of the predetermined period start trigger to the occurrence of the predetermined period end trigger;
Based on the fact that the predetermined period has been specified by the period elapse specifying unit, the predetermined value derived by the information deriving unit using the history information stored in the history storage unit A function for executing the processing of step SA203 and step SA216 in the main CPU 63 that stores the mode information corresponding to the result of the game in the period in the mode information storage unit (calculation result storage area 234) as the period corresponding mode information. )When,
Equipped with
The aspect information display control means controls the display of the information display means so that a display corresponding to the period corresponding aspect information stored in the aspect information storage means is performed.
The predetermined correspondence display control means is configured to display the predetermined correspondence display on the information display means on the assumption that the predetermined display trigger has occurred when the predetermined period has been specified by the period elapse specifying means. The gaming machine according to feature k14, which is characterized by being performed.

According to the feature k15, the past aspect information derived in units of a predetermined period is stored as the period corresponding aspect information, and the information corresponding to the period corresponding aspect information is displayed on the information display means. Thereby, the manager of the game hall can grasp the past period corresponding mode information derived in units of a predetermined period by checking the information display means. Further, when the predetermined period has elapsed, after the predetermined correspondence display is performed by the information display means, the display corresponding to the period correspondence mode information newly derived as the predetermined period has elapsed is performed. Thereby, whether the display corresponding to the period corresponding mode information on the information display means is the display corresponding to the period corresponding mode information newly derived based on the lapse of a predetermined period is determined by the manager of the game hall. Can be grasped. Further, since it becomes possible to display the predetermined correspondence display during the period during which the period correspondence mode information is being derived, the predetermined period has elapsed and the period correspondence mode information is being derived. Nevertheless, regardless of that, it is possible to prevent the display corresponding to the period correspondence mode information from being performed.

Feature k16. The predetermined correspondence display control means causes the information display means to perform the predetermined correspondence display for a period longer than the longest period required for deriving the one aspect information by the information deriving means. The gaming machine according to feature k15.

According to the characteristic k16, when the predetermined period has elapsed and the period correspondence mode information is being derived, the information display means displays the predetermined correspondence.

For the configurations of the features k1 to k16, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, Any one or a plurality of configurations of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature 1 group>
Feature l1. When a predetermined event occurs due to the execution of a game, history storage execution means (normal entrance management processing in the main CPU 63) for storing history information of the game corresponding to it in the history storage means (normal counter area 231) Function to execute)
Information derivation means (a function of executing the process of step SA201 in the main CPU 63) for deriving mode information (base value) corresponding to the result of the game using the history information stored in the history storage means,
Mode information storage means (operation result storage area 234) for storing the mode information derived by the information derivation means,
Mode information display control means (main side) for controlling display of the information display means (first to fourth notification display devices 201 to 204) so that the display corresponding to the mode information stored in the mode information storage means is performed A function of executing display processing and second timer interrupt processing in the CPU 63),
Equipped with
The aspect information storage means stores a plurality of specific storage areas (current area 311 and first history area 312) so as to be able to store each of the plurality of aspect information derived at different timings by the information derivation means. , A second history area 313, a third history area 314),
The aspect information display control means controls the information display means so that the display corresponding to each of the plurality of aspect information stored in the plurality of specific storage areas is sequentially executed according to a predetermined display order. Characteristic game machine.

According to the characteristic l1, when the predetermined event occurs, the history information corresponding to the predetermined event is stored in the history storage means. By storing the history information in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, the mode information corresponding to the result of the game is derived by using the history information stored in the history storage means, and the information display means performs the display corresponding to the derived mode information. Thereby, it becomes possible to grasp the management result of the game history such as the frequency of occurrence of the predetermined event.

Further, since a plurality of aspect information items having different derived timings are stored in the aspect information storage means and the notifications corresponding to the plurality of aspect information items are sequentially executed, the number of information display means can be reduced. It is possible to individually grasp the frequency of occurrence of a predetermined event in a plurality of periods. Further, since the display corresponding to each of the plurality of mode information stored in the plurality of specific storage areas is sequentially executed in accordance with the predetermined display order, the manager of the game hall grasps the type of mode information to be displayed. Easier to do.

Feature l2. The gaming machine according to feature 11, wherein a predetermined display order is set in association with the plurality of specific storage areas.

According to the characteristic l2, since the predetermined display order of the display corresponding to the aspect information is determined in association with the plurality of specific storage areas, the display target is set when the display corresponding to one aspect information is newly started. It is possible to simplify the processing configuration for specifying the type of the aspect information.

Feature l3. A predetermined correspondence display (pre-shift display) is performed on the information display means before a display corresponding to the aspect information is newly started based on occurrence of a predetermined display trigger. Control means (function of executing the processing of step SA320 and the second timer interrupt processing in the main CPU 63),
When the mode information display control means causes the information display means to display the information corresponding to the mode information after the predetermined corresponding display is performed by the information display means, 13. The gaming machine according to the characteristic l1 or l2, which is started from a display corresponding to the corresponding aspect information.

According to the characteristic l3, after the predetermined correspondence display is performed based on the occurrence of the predetermined display trigger, the display corresponding to the mode corresponding to the first order in the predetermined display order is started. Accordingly, when a predetermined display trigger occurs, it is possible to confirm the display corresponding to the information again from the first order of the predetermined display order.

Feature l4. A period elapse specifying unit (a function of executing the process of step SA210 in the main CPU 63) that specifies that a predetermined period has elapsed from the occurrence of the predetermined period start trigger to the occurrence of the predetermined period end trigger;
The predetermined period derived by the information deriving unit using the history information stored in the history storage unit based on the fact that the predetermined period has been identified by the period lapse identifying unit. Storage execution means for storing the mode information corresponding to the result of the game in the period as the period-corresponding mode information in the plurality of specific storage areas (function of executing the processes of step SA203 and step SA216 in the main CPU 63),
Equipped with
Any one of the characteristics 11 to 13 characterized in that the storage execution means causes the period correspondence mode information to be stored in the plurality of specific storage areas in the order derived by the information derivation means. The gaming machine described in 1.

According to the characteristic l4, it becomes possible to confirm the period corresponding mode information in the derived order.

Feature l5. From the situation in which the display corresponding to the mode information is being performed, the information display means is set to the pre-switching state (state of non-display for interval) before displaying the mode information different from the mode information. The gaming machine according to any one of features 11 to 14, characterized in that it has a means (function of executing the process of step SA316 and the second timer interrupt process in the main CPU 63).

According to the feature l5, when the mode information to be displayed is switched, the information display means is in the pre-switching state, so that the manager of the game hall clearly indicates that the mode information to be displayed has been switched. It becomes possible to grasp.

For the configurations of the features l1 to l5, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature m group>
Features m1. When a predetermined event occurs due to the execution of a game, history storage execution means (normal entrance management processing in the main CPU 63) for storing history information of the game corresponding to it in the history storage means (normal counter area 231) Function to execute)
Information derivation means (a function of executing the process of step SA201 in the main CPU 63) for deriving mode information (base value) corresponding to the result of the game using the history information stored in the history storage means,
Equipped with
The information derivation means performs an information derivation process for deriving the aspect information based on the occurrence of a process execution trigger, and derives the aspect information after starting the derivation of the aspect information. A gaming machine, characterized in that the information derivation process is executed a plurality of times until the completion of.

According to the feature m1, when the predetermined event occurs, the history information corresponding to the predetermined event is stored in the history storage means. By storing the history information in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, by using the history information stored in the history storage means to derive mode information corresponding to the result of the game in a predetermined period, the management result of the game history such as the frequency of occurrence of the predetermined event is grasped. It becomes possible. Further, since the information derivation process is executed a plurality of times from the start of derivation of the form information to the completion of the derivation of the form information, compared to the configuration in which the derivation of the form information is completed in one information derivation process. It is possible to reduce the processing load for executing the information derivation process.

Features m2. A period elapse specifying unit (a function of executing the process of step SA210 in the main CPU 63) that specifies that a predetermined period has elapsed from the occurrence of the predetermined period start trigger to the occurrence of the predetermined period end trigger;
Based on the fact that the predetermined period has been specified by the period elapse specifying unit, the predetermined value derived by the information deriving unit using the history information stored in the history storage unit A function for executing the processing of step SA203 and step SA216 in the main CPU 63 that stores the mode information corresponding to the result of the game in the period in the mode information storage unit (calculation result storage area 234) as the period corresponding mode information. )When,
Mode information display control means for controlling the display of the information display means (first to fourth notification display devices 201 to 204) so that the display corresponding to the period corresponding mode information stored in the mode information storage means is performed ( A function of executing display processing and second timer interrupt processing in the main CPU 63),
A predetermined correspondence display control unit (step SA320 in the main CPU 63 that causes the predetermined display to be performed on the information display unit based on the fact that the predetermined period has been specified by the period elapsed specifying unit). And the function of executing the second timer interrupt process),
The gaming machine described in the feature m1 is characterized by including the following.

According to the characteristic m2, the past aspect information derived in units of a predetermined period is stored as the period corresponding aspect information, and the information corresponding to the period corresponding aspect information is displayed on the information display means. Thereby, the manager of the game hall can grasp the past period corresponding mode information derived in units of a predetermined period by checking the information display means. Further, when the predetermined period has elapsed, after the predetermined correspondence display is performed by the information display means, the display corresponding to the period correspondence mode information newly derived as the predetermined period has elapsed is performed. Thereby, whether the display corresponding to the period corresponding mode information on the information display means is the display corresponding to the period corresponding mode information newly derived based on the lapse of a predetermined period is determined by the manager of the game hall. Can be grasped. Further, since it becomes possible to display the predetermined correspondence display during the period during which the period correspondence mode information is being derived, the predetermined period has elapsed and the period correspondence mode information is being derived. Nevertheless, regardless of that, it is possible to prevent the display corresponding to the period correspondence mode information from being performed.

Features m3. The predetermined correspondence display control means causes the information display means to perform the predetermined correspondence display for a period longer than the longest period required for deriving the one aspect information by the information deriving means. The gaming machine according to feature m2.

According to the feature m3, when the predetermined period has passed and the period correspondence mode information is being derived, the information display means displays the predetermined correspondence.

For the configurations of the features m1 to m3, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the inventions related to the characteristic k group, the characteristic l group, and the characteristic m group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, in a pachinko machine, the game machine front face section is provided with a dish storage section for storing the game balls given to the player, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, it is necessary to manage the gaming machine appropriately, and there is still room for improvement in this respect.

<Feature n group>
Features n1. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (function of executing the processing of step SA709 in the main CPU 63),
Change of the setting value to be used based on the fact that the first setting-related operation (ON operation of the setting key insertion portion 68a and pressing operation of the reset button 68c) is performed when the supply of operating power is started. Situation generating means (a function and a step of making an affirmative determination in step SA412 in the main CPU 63 in the 45th embodiment) so as to be in a settable state (a situation in which the setting value updating process is executed) A function to make an affirmative judgment in SA417, a function to make an affirmative judgment in steps SA905 and SA916 in the main CPU 63 in the 46th embodiment, and a function to make an affirmative judgment in step SA917).
Based on the fact that the second setting-related operation (ON operation of the setting key insertion portion 68a) is performed when the supply of operating power is started, the setting value to be used set by the setting means is Notification generating means (function of executing processing for setting confirmation in the main CPU 63) to be notified,
Equipped with
The status generating means can perform the setting even if the second setting-related operation is performed when the supply of the operating power is stopped in the middle of the settable status and when the supply of the operating power is started after that. Post-start generation means for making the situation (function of making a positive determination in step SA412 in the main CPU 63 in the 45th embodiment, positive determination in steps SA905 and SA916 in the main CPU 63 in the 46th embodiment A game machine characterized by having a function of performing.

According to the characteristic n1, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage degree of the player, the player can use the more advantageous setting value as the usage target. Will be expected. Also, in order to change the setting value to be used, it is necessary to perform the first setting-related operation when the supply of operating power is started, so an act of illegally changing the setting value to be used It is possible to make it difficult to perform. Further, when the supply of operating power is started, the setting value of the usage target is notified by performing the second setting related operation, so that the manager of the game hall confirms the setting value of the usage target as necessary. It becomes possible.

In addition, even if the second setting-related operation is performed when the supply of the operating power is stopped in the middle of the settable status and then the supply of the operating power is started, the settable status is set. As a result, when the supply of operating power is stopped while changing the set value to be used, when the supply of operating power is resumed after that, the setting of the used target is set rather than the notification of the set value of the used target. It becomes possible to give priority to the change of the value, and it is possible to prevent the game from being started even though the change of the set value to be used is not actually completed.

Feature n2. Situation notifying means (function for executing the processing of steps SA801 to SA803 in the main CPU 63 and function for executing the second timer interrupt processing) for notifying the set value being changed in the settable status is provided. The gaming machine described in the characteristic n1.

According to the feature n2, since the set value being changed is notified in the settable state, it is possible to change the set value while grasping the current set value. Further, in this way, the setting value being changed in the settable status is notified, so that the settable status is set even if the second setting-related operation is performed when the supply of the operating power is started. Even if the value change operation is prioritized, the set value can be substantially confirmed.

Feature n3. Both the status notification means and the notification generation means are configured to display a target set value on a predetermined display means (first to fourth notification display devices 201 to 204). The gaming machine described in n2.

According to the feature n3, the target setting value is displayed on the predetermined display means regardless of whether the setting value is changed or the setting value is confirmed. On the other hand, it becomes possible to use a predetermined display means. In addition, even if the setting is possible even if the second setting-related operation is performed when the supply of the operating power is started, the setting value is displayed on the predetermined display means when the setting is possible. Is displayed, the manager of the game hall who has performed the second setting-related operation can confirm the set value by visually observing the predetermined display means.

Feature n4. In the characteristic n3, the status notifying means causes the display corresponding to the setting value being changed and the display corresponding to the setting possible status to be performed on the predetermined display means. The game machine described.

According to the feature n4, when the setting is possible, not only the display corresponding to the set value being changed is displayed on the predetermined display means, but also the display corresponding to the setting possible. As a result, when the supply of the operating power is stopped in the middle of the settable status and the supply of the operating power is then started, the second setting-related operation is performed, but the settable status is set. In this case, it becomes easy for the manager of the gaming hall to know that the setting is possible.

Feature n5. In the case where the setting possible state is set, the generation means after start enables the setting value to be changed from the setting value selected when the supply of the operating power is stopped in the middle of the setting possible state. The gaming machine according to any one of the features n1 to n4.

According to the feature n5, even if the supply of the operating power is stopped in the middle of the settable state, when the supply of the operating power is resumed, the setting value is changed from the state immediately before the supply of the operating power is stopped. It is possible to continue the operation.

Features n6. Setting correspondence storage means (setting reference area 341) for storing setting correspondence information corresponding to the setting value set by the setting means,
A selection correspondence storage unit (setting update area 342) for storing selection correspondence information corresponding to the setting value selected in the setting possible state;
Equipped with
The situation generation means changes the selection correspondence information stored in the selection correspondence storage means so that a setting value that is a selection target is changed when a change trigger occurs in the setting possible status. (Function of executing the process of step SA708 in the main CPU 63),
The setting means stores information corresponding to the selection correspondence information stored in the selection correspondence storage means as the setting correspondence information in the setting correspondence storage means when an ending trigger occurs in the setting possible situation. According to the above, the setting value that was the selection target in the setting possible status is set as the usage target,
In the case where the setting possible status is set, the post-start generation means sets the setting corresponding to the selection correspondence information stored in the selection correspondence storage means when the supply of the operating power is stopped in the middle of the setting possible status. The game machine according to any one of features n1 to n5, wherein the setting value can be changed from a value.

According to the feature n6, the setting correspondence storing means for storing the setting correspondence information corresponding to the setting value to be used and the selection correspondence storing means for storing the selection correspondence information corresponding to the setting value being changed in the settable state are provided. By being provided, it becomes possible to change the set value in the settable situation while storing and holding the information of the set value set before the start of the settable situation. In this case, when the supply of the operating power is resumed after the supply of the operating power is stopped in the midst of the settable state, it is stored in the selection correspondence storage means when the supply of the operating power is stopped. The setting value corresponding to the selection correspondence information is changed. As a result, even if the supply of operating power is stopped in the middle of the settable status, if the supply of operating power is restarted, the operation to change the set value will continue from the state immediately before the supply of operating power was stopped. It becomes possible to do it.

Feature n7. The status generating means may include: when the supply of the operating power is stopped in the middle of the settable status and when the supply of the operating power is subsequently started, the first setting-related operation is performed; Means for enabling the setting value to be changed from the setting value corresponding to the setting correspondence information stored in the setting correspondence storage means (function for making a positive determination in step SA417 in the main CPU 63 in the 45th embodiment, In the forty-sixth embodiment, the gaming machine described in the feature n6 is provided with a function of making an affirmative determination in step SA917 in the main CPU 63.

According to the feature n7, the supply of the operating power is stopped when the second setting-related operation is performed when the supply of the operating power is restarted after the supply of the operating power is stopped in the middle of the settable state. While it is possible to restart the change of the set value from the set value that was the target of change before the setting is stopped, the supply of the operating power is restarted after the supply of the operating power is stopped in the middle of the settable status. When the second setting-related operation is performed, the setting value corresponding to the setting correspondence information stored in the setting correspondence storage means is changed. This makes it possible to make the initial set value when changing the set value different depending on the operation content when the supply of operating power is restarted.

Feature n8. The post-start generation means is configured to perform the first setting-related operation and the second setting-related operation when the supply of the operating power is stopped in the middle of the setting possible state and the supply of the operating power is started after that. The gaming machine according to any one of features n1 to n7, wherein the setting possible state can be set even when no operation is performed.

According to the characteristic n8, both the first setting-related operation and the second setting-related operation are performed when the supply of the operating power is stopped when the supply of the operating power is stopped in the middle of the settable state. Even if the setting value is not set, the setting value may change, so if the operating power supply is stopped while changing the setting value, change the setting value when the operating power supply is restarted. It is possible to positively generate a situation in which it is possible.

Feature n9. The first setting-related operation includes that the setting key inserting section (setting key inserting section 68a) is in a predetermined corresponding state (state of being turned on) by the setting key,
The situation generation means ends the settable situation based on the fact that the setting key insertion portion specifies that the predetermined correspondence state has been changed from the predetermined correspondence state to the specific correspondence state (state that has been turned off) by the setting key. The gaming machine according to any one of features n1 to n8, which is provided with means (a function of executing the processing of step SA709 and step SA710 in the main CPU 63).

According to the feature n9, since it is necessary to use the setting key to bring the setting key insertion part into a predetermined corresponding state in order to make the setting possible, it is possible to illegally change the setting value to be used. It is possible to make it difficult to do. In this case, the settable status does not end only when the setting key insertion unit is in the specific correspondence state, but ends when the setting key insertion unit is changed from the predetermined correspondence state to the specific correspondence state. As a result, even if the supply of the operating power is stopped in the middle of the settable status and then the supply of the operating power is started in the situation in which the setting key insertion section is in the specific support state, the settable status is immediately set. It is not ended, and the setting possible status is ended by changing the setting key insertion part from the specific correspondence state to the predetermined correspondence state and then further changing from the predetermined correspondence state to the specific correspondence state. It is possible to end the settable status at a timing that is preferable for the user.

Feature n10. The situation generating means is provided when the supply of the operating power is stopped while the notification of the setting value of the use target is being performed by the notification generating means, and when the supply of the operating power is started after that. The gaming machine according to any one of features n1 to n9, wherein the setting possible state is set when the first setting-related operation is performed.

According to the characteristic n10, even if the supply of the operating power is stopped while the setting value to be used is being notified, the first setting-related operation is performed at the start of the subsequent supply of the operating power. Is settable status. This makes it possible to prioritize the work of changing the set value over the work of checking the set value.

For the configurations of the features n1 to n10, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, Any one or a plurality of configurations of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature o group>
Feature o1. Means for executing profit-giving processing in a mode corresponding to a setting value set as a usage target among setting values of a plurality of stages corresponding to the player's advantage (processing of steps S503 and S504 in the main CPU 63) Function to execute)
Setting-related executing means for executing a predetermined setting-related process relating to the set value (a function for executing a setting value update process in the main CPU 63, a function for executing a setting confirmation process in the main CPU 63);
Based on the fact that the supply of the operating power is stopped before the completion of the predetermined setting-related processing, the halfway restarting means for restarting the predetermined setting-related processing from the middle after the supply of the operating power is started thereafter ( In the 45th embodiment, the function of making an affirmative judgment in step SA412 in the main CPU 63 and the function of making an affirmative judgment in step SA414 in the main CPU 63. Function to make an affirmative decision)
A gaming machine characterized by being equipped with.

According to the characteristic o1, the setting value to be used is set from the setting values of the plurality of stages corresponding to the advantage of the player, so that the player can use the more advantageous setting value as the usage target. Will be expected. In this case, even if the supply of the operating power is stopped before the completion of the predetermined setting-related processing, the predetermined setting-related processing is restarted halfway when the supply of the operating power is restarted. As a result, even if the supply of the operating power is stopped during the predetermined setting-related process, the predetermined setting-related process can be continued when the supply of the operating power is restarted.

Feature o2. The setting-related execution means performs a predetermined setting-related operation (if the predetermined setting-related processing is a set value update processing, an ON operation of the setting key insertion portion 68a and a pressing operation of the reset button 68c, and a predetermined setting-related processing is for setting confirmation. In the case of processing, the predetermined setting-related processing is executed based on the fact that the setting key insertion section 68a is turned on).
The gaming machine according to feature o1, wherein the midway restarting means restarts the predetermined setting-related processing from the middle even if the predetermined setting-related operation is not performed.

According to the feature o2, when the supply of the operating power is stopped before the completion of the predetermined setting-related processing, the predetermined setting-related processing is restarted from the middle even if the predetermined setting-related operation is not performed. It is possible to give priority to the restart from the middle of the predetermined setting-related processing.

Feature o3. The setting-related executing means executes the predetermined setting-related processing based on the fact that the predetermined setting-related operation is performed when the supply of operating power is started,
The midway restarting means restarts the predetermined setting-related processing from the middle even if the predetermined setting-related operation is not performed when the supply of operating power is started,
When the supply of the operating power is stopped before the completion of the predetermined setting-related processing and then the supply of the operating power is started, and when the predetermined setting-related operation is performed, The gaming machine according to feature o2, wherein the predetermined setting-related processing is newly restarted by the setting-related executing means instead of being restarted from the middle.

According to the feature o3, since the predetermined setting-related process is executed based on the predetermined setting-related operation being performed when the supply of the operating power is started, the act of illegally executing the predetermined setting-related process It is possible to make it difficult to perform. In this case, even if the predetermined setting-related operation is not performed when the supply of the operating power is resumed after the supply of the operating power is stopped in the middle of the predetermined setting-related processing, the predetermined setting-related processing is still in progress. Since it is restarted from, it is possible to give priority to the restart from the middle of the predetermined setting related processing. On the other hand, if the predetermined setting-related operation is performed when the supply of the operating power is restarted after the supply of the operating power is stopped in the middle of the predetermined setting-related processing, the predetermined setting-related processing is performed from the middle. Instead of restarting, it starts anew. As a result, when the supply of the operating power is stopped during the predetermined setting-related process, the predetermined setting-related process is newly started depending on the presence or absence of the predetermined setting-related operation when the supply of the operating power is restarted. It is possible to select either to restart the predetermined setting-related processing from the middle.

Features o4. The predetermined setting-related operation includes that the setting key inserting section (setting key inserting section 68a) is in a predetermined corresponding state (state turned ON) by the setting key,
The setting-related execution means determines the predetermined setting-related processing based on the fact that the setting key insertion unit has specified that the predetermined corresponding state has been changed to the specific corresponding state (the OFF-operated state) by the setting key. In the feature o2 or o3, the main CPU 63 has means (a function of executing the process of step SA504 in the main CPU 63, a function of executing the processes of step SA709 and step SA710 in the main CPU 63). Amusement machine.

According to the feature o4, in order to start the predetermined setting-related processing, it is necessary to use the setting key to bring the setting key insertion unit into the predetermined corresponding state, and therefore, the act of illegally executing the predetermined setting-related processing is performed. It is possible to make it difficult to do. In this case, the predetermined setting-related process does not end only when the setting key insertion unit is in the specific correspondence state, but ends when the setting key insertion unit is changed from the predetermined correspondence state to the specific correspondence state. As a result, even if the supply of the operating power is stopped before the completion of the predetermined setting-related processing and the supply of the operating power is started in the situation where the setting key insertion section is in the specific correspondence state after that, the supply of the operating power is immediately performed. The predetermined setting-related processing is not ended, and the predetermined setting-related processing is ended by changing the setting key insertion part from the specific correspondence state to the predetermined correspondence state and then further changing from the predetermined correspondence state to the specific correspondence state. Therefore, the predetermined setting-related processing can be ended at a timing that is preferable for the manager of the game hall.

Features o5. The gaming machine according to any one of features o1 to o4, wherein the predetermined setting-related process is a process for changing a setting value to be used.

According to the feature o5, even if the supply of the operating power is stopped while the set value is being changed, when the supply of the operating power is restarted, the set value is changed from the set value being changed. It becomes possible to restart. As a result, even if the supply of the operating power is stopped while the set value is being changed, it is possible to continue the work of changing the set value when the supply of the operating power is restarted.

Features o6. The predetermined setting-related processing is processing for changing a setting value to be used,
A setting correspondence storage means (setting reference area 341) for storing setting correspondence information corresponding to the setting value to be used,
A selection correspondence storage unit (setting update area 342) for storing selection correspondence information corresponding to the setting value selected in the predetermined setting-related processing;
Equipped with
The setting related execution means,
As the predetermined setting-related processing, a unit that changes the selection correspondence information stored in the selection correspondence storage unit so that the setting value that is a selection target is changed when a change trigger occurs (main side). A function of executing the processing of step SA708 in the CPU 63),
As the predetermined setting-related processing, by storing information corresponding to the selection correspondence information stored in the selection correspondence storage means when the termination trigger occurs in the setting correspondence storage means as the setting correspondence information, Means for setting the set value that was the selection target as the usage target (function of executing the processing of step SA709 in the main CPU 63);
Equipped with
The midway resuming means selects the setting value from the setting value corresponding to the selection correspondence information stored in the selection correspondence storage means when the supply of the operating power is stopped before completing the predetermined setting related processing. The gaming machine according to any one of the features o1 to o5, wherein the gaming machine can be changed.

According to the feature o6, the setting correspondence storing means for storing the setting correspondence information corresponding to the setting value to be used and the selection correspondence storing means for storing the selection correspondence information corresponding to the setting value being changed in the settable state are provided. By being provided, it becomes possible to change the set value in the settable situation while storing and holding the information of the set value set before the start of the settable situation. In this case, if the supply of the operating power is resumed after the supply of the operating power is stopped while the set value is being changed, the selection correspondence storage means stores the supply of the operating power when the supply of the operating power is stopped. The setting value is changed from the setting value corresponding to the selected correspondence information. As a result, even if the supply of operating power is stopped while the set value is being changed, if the supply of operating power is restarted, the setting value will be changed from the state immediately before the supply of operating power was stopped. It is possible to continue the operation.

Features o7. The setting-related executing means executes the predetermined setting-related processing based on a predetermined setting-related operation being performed when the supply of operating power is started,
The midway restarting means restarts the predetermined setting-related processing from the middle based on the fact that the predetermined setting-related operation is not performed when the supply of the operating power is started,
The setting-related executing means performs the predetermined setting-related operation when the supply of the operating power is stopped after the supply of the operating power is stopped before the completion of the predetermined setting-related process. Means for enabling the setting value to be changed from the setting value corresponding to the setting correspondence information stored in the setting correspondence storage means (in the 45th embodiment, a positive determination is made in step SA417 in the main CPU 63). The gaming machine according to feature o6, which has a function, in the 46th embodiment, a function for making an affirmative decision in step SA917 in the main CPU 63).

According to the feature o7, when the supply of the operating power is resumed after the supply of the operating power is stopped while the setting value is being changed, the operating power based on the fact that the predetermined setting related operation is not performed is performed. It is possible to restart the change of the set value from the set value that was the change target before the supply of the power was stopped, while the supply of operating power was stopped while changing the set value. If the predetermined setting-related operation is performed when the supply of the operating power is restarted, the setting value corresponding to the setting correspondence information stored in the setting correspondence storage means is changed. This makes it possible to make the initial set value when changing the set value different depending on the operation content when the supply of operating power is restarted.

For the configurations of the features o1 to o7, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature p group>
Features p1. Means for executing profit-giving processing in a mode corresponding to a setting value set as a usage target among setting values of a plurality of stages corresponding to the player's advantage (processing of steps S503 and S504 in the main CPU 63) Function to execute)
Predetermined setting related operation (if the predetermined setting related process is a set value update process, ON operation of the setting key insertion unit 68a and pressing of the reset button 68c, and if the predetermined setting related process is a setting confirmation process, set key insertion The setting-related executing means (the function of executing the setting value updating process in the main CPU 63) that executes a predetermined setting-related process relating to the setting value based on the fact that the ON operation of the section 68a is performed, and the setting in the main CPU 63. Function to execute confirmation process),
If the supply of operating power is stopped before the completion of the predetermined setting-related processing, the setting-related execution means does not perform the predetermined setting-related operation after the supply of operating power is started after that. Also, after-supply execution means for executing the predetermined setting-related processing (in the 45th embodiment, the function of making a positive determination in step SA412 in the main CPU 63 and the function of making a positive determination in step SA414 in the main CPU 63, In the forty-sixth embodiment, a gaming machine having a function of making an affirmative judgment in steps SA905 and SA916 in the main CPU 63).

According to the characteristic p1, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player can use the more advantageous setting value as the usage target. Will be expected. In addition, it is possible to execute a predetermined setting-related process by performing a predetermined setting-related operation. In this case, even if the supply of the operating power is stopped before the completion of the predetermined setting-related processing, if the supply of the operating power is restarted, the predetermined setting is performed even if the predetermined setting-related operation is not performed. Related processing is executed. This makes it possible to give priority to the execution of the predetermined setting-related processing.

Features p2. The setting-related executing means executes the predetermined setting-related processing based on the fact that the predetermined setting-related operation is performed when the supply of operating power is started,
The gaming machine according to feature p1, wherein the after-execution executing unit executes the predetermined setting-related process even if the predetermined setting-related operation is not performed when the supply of the operating power is started. ..

According to the characteristic p2, the predetermined setting-related process is executed based on the fact that the predetermined setting-related operation is performed when the supply of the operating power is started, so that the predetermined setting-related process is illegally executed. It is possible to make it difficult to perform. In this case, the predetermined setting-related process is executed even if the predetermined setting-related operation is not performed when the supply of the operating power is restarted after the supply of the operating power is stopped in the middle of the predetermined setting-related process. Therefore, it is possible to give priority to the execution of the predetermined setting-related processing.

Features p3. The predetermined setting-related operation includes that the setting key inserting section (setting key inserting section 68a) is in a predetermined corresponding state (state turned ON) by the setting key,
The setting-related execution means determines the predetermined setting-related processing based on the fact that the setting key insertion unit has specified that the predetermined corresponding state has been changed to the specific corresponding state (the OFF-operated state) by the setting key. The feature p1 or p2 is characterized in that it is provided with means (a function for executing the process of step SA504 in the main CPU 63, a function for executing the processes of step SA709 and step SA710 in the main CPU 63) for terminating the process. Amusement machine.

According to the characteristic p3, in order to start the predetermined setting-related processing, it is necessary to use the setting key to bring the setting key insertion unit into the predetermined corresponding state, and therefore, the act of illegally executing the predetermined setting-related processing is performed. It is possible to make it difficult to do. In this case, the predetermined setting-related process does not end only when the setting key insertion unit is in the specific correspondence state, but ends when the setting key insertion unit is changed from the predetermined correspondence state to the specific correspondence state. As a result, even if the supply of the operating power is stopped before the completion of the predetermined setting-related processing and the supply of the operating power is started in the situation where the setting key insertion section is in the specific correspondence state after that, the supply of the operating power is immediately performed. The predetermined setting-related processing is not ended, and the predetermined setting-related processing is ended by changing the setting key insertion part from the specific correspondence state to the predetermined correspondence state and then further changing from the predetermined correspondence state to the specific correspondence state. Therefore, the predetermined setting-related processing can be ended at a timing that is preferable for the manager of the game hall.

Features p4. The post-supply execution means performs the specific related operation when the supply of the operating power is started after that even when the supply of the operating power is stopped before the completion of the predetermined setting related processing. The gaming machine according to any one of the features p1 to p3, wherein the predetermined setting-related processing is not executed.

According to the characteristic p4, even when the supply of the operating power is stopped before the completion of the predetermined setting related process, the specific related operation is performed when the supply of the operating power is started after that. Does not execute the predetermined setting-related processing. As a result, even if the supply of the operating power is stopped before the completion of the predetermined setting-related process, the supply of the operating power is started when it is not necessary to execute the predetermined setting-related process thereafter. In this case, by performing the specific related operation, it is possible to prevent the predetermined setting related processing from being executed.

Features p5. The gaming machine according to any one of features p1 to p4, wherein the predetermined setting-related processing is processing for notifying a setting value to be used.

According to the characteristic p5, when the supply of the operating power is stopped while the notification of the set value is being performed, the predetermined setting related operation is not performed when the supply of the operating power is started after that. Also, the notification of the set value is restarted. This makes it possible to give priority to the notification of the set value.

Features p6. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (function of executing the processing of step SA709 in the main CPU 63),
Based on the fact that a specific related operation (ON operation of the setting key insertion portion 68a and pressing operation of the reset button 68c) is performed when the supply of operating power is started, the setting value to be used is changed. Situation generating means for setting a possible settable situation (situation in which the set value updating process is executed) (in the 45th embodiment, the function of making a positive determination in step SA412 in the main CPU 63 and step SA417). A function to make an affirmative judgment in the 46th embodiment, a function to make an affirmative judgment in steps SA905 and SA916 in the main CPU 63, and a function to make an affirmative judgment in step SA917).
Equipped with
The post-supply execution unit performs the specific related operation when the supply of the operating power is started after that even if the supply of the operating power is stopped before the completion of the predetermined setting related processing. If this happens, the predetermined setting related processing is not executed,
Even when the supply of the operating power is stopped before the predetermined setting-related processing is completed, the situation generating means performs the specific related operation when the supply of the operating power is started after that. In the case of the above, the gaming machine described in the characteristic p5 is characterized in that the setting possible state is set.

According to the characteristic p6, even when the supply of the operating power is stopped while the notification of the set value is being performed, the specific related operation is performed when the supply of the operating power is started after that. In this case, the notification of the set value is not performed, but the settable state in which the set value can be changed is set. This makes it possible to prioritize the occurrence of the settable status over the notification of the set value when a specific related operation for making the settable status in which the set value can be changed is performed.

Features p7. The gaming machine according to any one of features p1 to p6, wherein the predetermined setting-related processing is processing for changing a setting value to be used.

According to the characteristic p7, even if the supply of the operating power is stopped while the setting value is being changed, it is possible to change the setting value when the supply of the operating power is restarted. As a result, even if the supply of the operating power is stopped while the set value is being changed, it is possible to continue the work of changing the set value when the supply of the operating power is restarted.

In addition, with respect to the configurations of the features p1 to p7, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature q group>
Features q1. Means for executing profit-giving processing in a mode corresponding to a setting value set as a usage target among setting values of a plurality of stages corresponding to the player's advantage (processing of steps S503 and S504 in the main CPU 63) Function to execute)
Setting-related executing means for executing a predetermined setting-related process relating to the set value (a function for executing a setting value update process in the main CPU 63, a function for executing a setting confirmation process in the main CPU 63);
Equipped with
Even if the supply of the operating power is stopped before the predetermined setting-related processing is completed, the setting-related executing means performs the specific related operation (the predetermined setting-related processing when the supply of the operating power is started after that). If the setting confirmation process is a RAM clear operation or a setting change operation, and if the predetermined setting related process is a set value update process, a RAM clear operation), the predetermined setting related process is not executed. Characteristic game machine.

According to the characteristic q1, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the degree of advantage of the player, the player can use the more advantageous setting value as the usage target. Will be expected. In this case, even if the supply of the operating power is stopped before the completion of the predetermined setting-related process, the predetermined operation is performed when the supply of the operating power is started after that. Setting related processing of is not executed. As a result, even if the supply of the operating power is stopped before the completion of the predetermined setting-related process, the supply of the operating power is started when it is not necessary to execute the predetermined setting-related process thereafter. In this case, by performing the specific related operation, it is possible to prevent the predetermined setting related processing from being executed.

Features q2. The gaming machine according to feature q1, wherein the predetermined setting-related process is a process for notifying a setting value to be used.

According to the feature q2, even if the supply of the operating power is stopped during the notification of the set value, if the specific related operation is performed when the supply of the operating power is started after that, the setting is performed. Value notification does not resume. As a result, even if the supply of the operating power is stopped during the notification of the set value and it is not necessary to notify the set value after that, when the supply of the operating power is started. By performing the specific related operation, it is possible to prevent the setting value from being notified.

Features q3. The setting-related execution means performs a predetermined setting-related operation (if the predetermined setting-related processing is a set value update processing, an ON operation of the setting key insertion portion 68a and a pressing operation of the reset button 68c, a predetermined setting-related processing is for confirming the setting In the case of processing, the predetermined setting-related processing is executed based on the fact that the setting key insertion section 68a is turned on), and the operating power is supplied before the predetermined setting-related processing is completed. A feature that the predetermined setting-related processing is not executed when the specific related operation is performed instead of the predetermined setting-related operation when the supply of the operating power is started after the operation is stopped The gaming machine described in q1 or q2.

According to the characteristic q3, since it is necessary to perform the predetermined setting-related operation in order to perform the predetermined setting-related processing, it is possible to make it difficult to perform the act of illegally executing the predetermined setting-related processing.

Features q4. The setting related execution means does not perform the specific related operation when the supply of the operating power is stopped before the completion of the predetermined setting related process and the supply of the operating power is started after that. In this case, the means for executing the predetermined setting-related processing even if the predetermined setting-related operation is not performed (in the 45th embodiment, the function of making a positive determination in step SA412 of the main-side CPU 63 and the main-side CPU 63). The gaming machine according to feature q3, which is provided with a function of making an affirmative determination in step SA414).

According to the feature q4, when the supply of the operating power is stopped before the completion of the predetermined setting-related process, the predetermined setting-related operation is performed depending on whether or not the specific related operation is performed when the supply of the operating power is started. It is possible to select whether or not the predetermined setting-related processing is executed without performing.

Features q5. The predetermined setting-related operation includes that the setting key inserting section (setting key inserting section 68a) is in a predetermined corresponding state (state turned ON) by the setting key,
The setting-related execution means determines the predetermined setting-related processing based on the fact that the setting key insertion unit has specified that the predetermined corresponding state has been changed to the specific corresponding state (the OFF-operated state) by the setting key. The game machine according to feature q4, characterized in that it is provided with a means for terminating the process (function for executing the process of step SA504 in the main CPU 63, function for executing the process of step SA709 and step SA710 in the main CPU 63). ..

According to the feature q5, in order to start the predetermined setting-related processing, it is necessary to use the setting key to bring the setting key insertion unit into the predetermined corresponding state, and therefore, the act of illegally executing the predetermined setting-related processing is performed. It is possible to make it difficult to do. In this case, the predetermined setting-related process does not end only when the setting key insertion unit is in the specific correspondence state, but ends when the setting key insertion unit is changed from the predetermined correspondence state to the specific correspondence state. As a result, even if the supply of the operating power is stopped before the completion of the predetermined setting-related processing and the supply of the operating power is started in the situation where the setting key insertion section is in the specific correspondence state after that, the supply of the operating power is immediately performed. The predetermined setting-related processing is not ended, and the predetermined setting-related processing is ended by changing the setting key insertion part from the specific correspondence state to the predetermined correspondence state and then further changing from the predetermined correspondence state to the specific correspondence state. Therefore, the predetermined setting-related processing can be ended at a timing that is preferable for the manager of the game hall.

Features q6. Based on the fact that the specific related operation is performed when the supply of the operating power is started, another execution means for executing another process different from the predetermined setting related process (the predetermined setting related process is for confirming the setting). If it is a process, the main CPU 63 executes only the RAM clear process and does not execute the set value update process, or the main CPU 63 executes the RAM clear process and the set value update process, and the predetermined setting related process is the set value. In the case of update processing, the main CPU 63 according to the forty-fifth embodiment has a function of executing only RAM clear processing and not executing set value update processing). Game machine.

According to the feature q6, when the supply of the operating power is stopped before the completion of the predetermined setting related process, the supply of the operating power is performed after that by using the specific related operation performed to execute another process. It is possible to prevent the predetermined setting related processing from being executed when the processing is started.

Features q7. Even if the supply of the operating power is stopped before the completion of the predetermined setting-related processing, the separate execution means determines that the specific related operation is performed when the supply of the operating power is started after that. The gaming machine according to feature q6, wherein the different process is executed based on the above.

According to the feature q7, even when the supply of the operating power is stopped before the completion of the predetermined setting related process, the specific related operation is performed when the supply of the operating power is started after that. It is possible to give priority to the execution of another process over the predetermined setting related process.

Feature q8. In the characteristic q6 or q7, the predetermined setting-related processing is processing for notifying a setting value to be used, and the different processing is processing for changing the setting value to be used. The game machine described.

According to the feature q8, even if the supply of the operating power is stopped during the notification of the set value, if the specific related operation is performed when the supply of the operating power is started after that, the setting is performed. Value notification does not resume. As a result, even if the supply of the operating power is stopped during the notification of the set value and it is not necessary to notify the set value after that, when the supply of the operating power is started. By performing the specific related operation, it is possible to prevent the setting value from being notified. Further, as the operation for preventing the notification of the set value in this way, it is possible to use the specific related operation for executing the process for changing the set value.

For the configurations of the features q1 to q8, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature r group>
Feature r1. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (function of executing the processing of step SA709 in the main CPU 63),
Situation generating means (in the 45th embodiment, the step SA412 in the main CPU 63 in the 45th embodiment) is such that the setting value to be used can be changed so that the setting value can be changed (the setting value updating process is executed). Function for making an affirmative judgment in step SA417, and function for making an affirmative judgment in step SA417 in the 46th embodiment, and function for making an affirmative judgment in step SA905 and step SA916 in the main CPU 63 and in step SA917. )When,
Setting correspondence storage means (setting reference area 341) for storing setting correspondence information corresponding to the setting value set by the setting means,
A selection correspondence storage unit (setting update area 342) for storing selection correspondence information corresponding to the setting value selected in the setting possible state;
Equipped with
The situation generation means changes the selection correspondence information stored in the selection correspondence storage means so that a setting value that is a selection target is changed when a change trigger occurs in the setting possible status. (Function of executing the process of step SA708 in the main CPU 63),
The setting means stores information corresponding to the selection correspondence information stored in the selection correspondence storage means as the setting correspondence information in the setting correspondence storage means when an ending trigger occurs in the setting possible situation. According to the above, the gaming machine is characterized in that the setting value that has been the selection target in the setting possible state is set as the usage target.

According to the characteristic r1, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player can set the more advantageous setting value to the use target. Will be expected. In this case, a setting correspondence storing means for storing the setting correspondence information corresponding to the setting value to be used and a selection correspondence storing means for storing the selection correspondence information corresponding to the setting value being changed in the settable state are provided. By doing so, it becomes possible to change the set value in the settable state while storing and holding the information of the set value set before the start of the settable state.

Feature r2. The situation generation means stores the setting correspondence situation that has been stored in the selection correspondence storage means in the previous setting possible situation in the setting possible situation that occurs after the setting possible situation ends before the termination trigger occurs. A feature r1 characterized by being provided with a first change execution means (a function of making an affirmative determination in step SA701 in the main CPU 63) capable of changing the set value from the set value corresponding to the selection correspondence information. The game machine described.

Feature r2. When the settable status starts after the settable status ends before the termination trigger occurs, the set value corresponding to the selection correspondence information stored in the selection correspondence storage means is changed. .. As a result, even if the settable status ends before the end trigger occurs, if the settable status is restarted, the operation to change the set value from the last selected set value in the previous settable status. Can be continued.

Feature r3. The situation generating means sets the setting corresponding to the setting correspondence information stored in the setting correspondence storing means in the setting possible situation generated after the setting possible situation ends before the termination trigger occurs. The gaming machine according to feature r2, which is provided with a second change execution unit (a function of making a negative determination in step SA701 in the main CPU 63) that enables a change of the set value from a value.

According to the feature r3, when the settable situation is started after the settable situation ends before the termination trigger occurs, the setting value is changed from the last selected set value in the previous settable situation. Not only it becomes possible to restart the setting correspondence information but also the setting correspondence information stored in the setting correspondence storage means when the setting possibility situation is started after the setting possibility situation ends before the termination trigger occurs. It becomes possible to change the set value from the set value to be set. This makes it possible to make the initial set value when changing the set value different depending on the situation when the settable situation is restarted.

Feature r4. The second change execution means sets the setting value corresponding to the setting correspondence information stored in the setting correspondence storage means in the setting possible situation that has occurred after the setting possible situation that ended when the termination trigger occurs. The game machine according to feature r3, wherein the setting value can be changed from

According to the characteristic r4, in a normal setting-possible situation, the setting value is changed from the current setting value of the object of use.

Feature r5. The situation generation means is based on that a specific related operation is performed when the settable situation is started after the settable situation ends before the termination trigger occurs in the settable situation. A situation in which the setting value corresponding to the selection correspondence information stored in the selection correspondence storage means can be changed and a setting corresponding to the setting correspondence information stored in the setting correspondence storage means It is provided with means (a function of executing the processing of step SA405, step SA412, and step SA417 in the main CPU 63) for making one of the situations in which the setting value can be changed from the value. The gaming machine according to feature r3 or r4.

According to the characteristic r5, when the settable status is started after the settable status ends before the termination trigger occurs, the set value of the set value is changed from the last selected set value in the previous settable status. It becomes possible for the manager of the game hall to select whether to restart the change or to start changing the set value from the set value of the current usage target.

Feature r6. The setting values corresponding to the selection correspondence information stored in the selection correspondence storage means in the settable state are displayed on predetermined display means (first to fourth notification display devices 201 to 204). The gaming machine according to any one of the features r1 to r5, which is provided with a means (a function of executing the processing of step SA801 to step SA803 in the main CPU 63).

According to the feature r6, it is possible to perform the setting value changing operation while confirming the setting value which is being changed in the settable state.

Feature r7. The display of the set value corresponding to the setting correspondence information stored in the setting correspondence storage means in a situation other than the setting possible situation is displayed on predetermined display means (first to fourth notification display devices 201 to 204). The gaming machine according to any one of features r1 to r6, which is provided with means (a function of executing the processing of steps SA601 to SA603 in the main CPU 63) to be performed.

According to the characteristic r7, it is possible to confirm the current setting value of the target of use, if necessary.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features r1 to r7. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the characteristic n group, the characteristic o group, the characteristic p group, the characteristic q group, and the characteristic r group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as exemplified above, it is necessary to make the configuration relating to the set value that determines the advantage of the gaming machine suitable, and there is still room for improvement in this respect.

<Feature s group>
Features s1. The predetermined corresponding processing (setting confirmation processing, set value updating processing) is started based on the fact that the predetermined key insertion portion (setting key insertion portion 68a) is brought into the predetermined corresponding state (state of being ON-operated) by the predetermined key. Predetermined correspondence starting means (in the 45th embodiment, the function of making an affirmative judgment in step SA413 in the main CPU 63 and the function of making an affirmative judgment in step SA 417 in the main CPU 63; in the 46th embodiment, the step in main CPU 63). The function of making an affirmative judgment in SA913 and the function of making an affirmative judgment in step SA917),
Predetermined response ending means (mainly) for terminating the predetermined response process based on the fact that the predetermined key insertion portion has specified that the predetermined corresponding state has been changed from the predetermined corresponding state to the specific corresponding state (state of being turned off) by the predetermined key. The function of executing the processing of step SA709 and step SA710 in the side CPU 63),
A gaming machine characterized by being equipped with.

According to the characteristic s1, since it is necessary to use the predetermined key to bring the predetermined key insertion part into the predetermined corresponding state in order to start the predetermined corresponding process, an action for illegally starting the predetermined corresponding process is performed. It is possible to make it difficult. In this case, the predetermined correspondence process does not end only when the predetermined key insertion portion is in the specific correspondence state, but ends when the predetermined key insertion portion is changed from the predetermined correspondence state to the specific correspondence state. As a result, even if the predetermined response processing is started in a situation where the predetermined key insertion section is in the specific response state for some reason, the predetermined response processing is not immediately terminated, and the predetermined key insertion section is moved from the specific response state to the specific response state. Since the predetermined correspondence process is ended by changing the predetermined correspondence state to the specific correspondence state after changing to the predetermined correspondence state, it is possible to end the predetermined correspondence process at a timing preferable for the manager of the game hall.

Features s2. Based on that the specific start condition is satisfied, another start means for starting the predetermined corresponding process in the situation where the predetermined key insertion part is in the specific corresponding state (in the 45th embodiment, step SA412 in main CPU 63). A function for making an affirmative judgment in step SA414 in the main CPU 63, and a function for making an affirmative judgment in step SA905 and step SA916 in the main CPU 63 in the 46th embodiment). The gaming machine described in the feature s1.

According to the characteristic s2, the predetermined response process is started even when the predetermined key insertion part is in the specific response state based on the fact that the specific start condition is satisfied. Therefore, there are various triggers for starting the predetermined response process. It becomes possible to make it. However, in the configuration, the predetermined correspondence processing is started in a situation where the predetermined key insertion portion is in the specific correspondence state. However, the predetermined correspondence processing is provided in the specific correspondence state when the predetermined key insertion portion is in the specific correspondence state. The above does not mean that the process is ended, but the process ends when the predetermined key insertion part is changed from the predetermined corresponding state to the specific corresponding state. As a result, even if the predetermined correspondence processing is started in a situation where the predetermined key insertion portion is in the specific correspondence state, the predetermined correspondence processing is not immediately terminated and the predetermined key insertion portion is changed from the specific correspondence state to the predetermined correspondence state. Since the predetermined correspondence process is ended by further changing the predetermined correspondence state from the predetermined correspondence state to the specific correspondence state after the change to, it is possible to end the predetermined correspondence process at a timing preferable for the manager of the game hall.

Features s3. The predetermined correspondence starting means starts the predetermined correspondence processing based on that the predetermined key insertion portion is in the predetermined correspondence state when supply of operating power is started,
The characteristic s2 is characterized in that the specific start condition is satisfied when the supply of the operating power is stopped and the supply of the operating power is restarted in the situation where the predetermined corresponding process is executed. Game machine.

According to the characteristic s3, when the supply of the operating power is started, the predetermined correspondence processing is started based on the predetermined key insertion portion being in the predetermined correspondence state. Therefore, the predetermined correspondence processing may be illegally started. It becomes possible to make it difficult to perform the act. Further, even if the supply of the operating power is stopped in the situation where the predetermined handling process is being executed, if the specific start condition is satisfied when the supply of the operating power is resumed, the predetermined key insertion part performs the predetermined handling. Even if it is not in the state, the predetermined handling process is started. This makes it possible to prioritize the start of the predetermined handling process when the predetermined handling process ends midway.

Features s4. Means for executing profit-giving processing in a mode corresponding to a setting value set as a usage target among setting values of a plurality of levels corresponding to the player's advantage (processing of steps S503 and S504 in the main CPU 63) Function to execute
The gaming machine according to any one of features s1 to s3, wherein the predetermined correspondence process is a process related to the set value.

According to the characteristic s4, it is possible to obtain the above-mentioned excellent effects for the processing related to the set value.

In addition, with respect to the configurations of the features s1 to s4, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the characteristic s group, it is possible to solve the following problems.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, for example, a lottery process is executed by the control means to determine whether or not to generate a game state advantageous to the player.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, it is necessary for the control means to appropriately perform the processing, and there is still room for improvement in this respect.

<Feature t group>
Feature t1. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (in the first embodiment, a function of executing the processing of steps S205 to S207 in the main CPU 63, In the eleventh embodiment, the main CPU 63 has a function of executing steps S3106 to S3108. In the twelfth embodiment, the main CPU 63 has a function of executing steps S3207 to S3209. The function of the main CPU 63 to execute the processing of steps S5605 to S5607, the function of the main CPU 63 to execute the processing of step SB311 in the 49th embodiment, and the 53rd embodiment of the main CPU 63 to the processing of step SB915. Function to execute)
Situation generating means (in the first embodiment, step S103 in the main CPU 63 in the first embodiment) to set a setting possible state (a setting value update process is executed) in which the setting value to be used can be changed. Function for making an affirmative judgment in the 22nd embodiment, a function for making an affirmative judgment in steps S5503 to S5507 in the main CPU 63, and a function for making an affirmative judgment in step SB113 in the main CPU 63 in the 49th embodiment. In the 53rd embodiment, a function of making a positive determination in step SB812 in the main CPU 63),
In the case where the settable status is reached, a start correspondence means for changing the set value from a preset start correspondence set value (in the first embodiment, the processing of step S201 in the main CPU 63 is executed. Functions, in the eleventh embodiment the main CPU 63 executes the process of step S3102, in the twelfth embodiment the main CPU 63 executes the process of step S3203, and in the twenty-second embodiment the main CPU 63 executes the process. A function of executing the process of step S5601, a function of executing the process of step SB304 in the main CPU 63 in the 49th embodiment, a function of executing the process of step SB905 in the main CPU 63 in the 53rd embodiment),
A gaming machine characterized by being equipped with.

According to the characteristic t1, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player can use the more advantageous setting value as the usage target. Will be expected. In this case, when the setting is possible, the setting value is changed from the setting value corresponding to the predetermined start. As a result, regardless of the set value of the object to be used before the settable status is reached, the set value can be changed from the set value corresponding to a certain start in the settable status. Therefore, the work content of the operation of changing the set value becomes easy for the operator to understand.

Feature t2. The gaming machine according to feature t1, wherein the setting value corresponding to the start is a setting value having the lowest advantage (“setting 1”).

According to the characteristic t2, when the setting is possible, the setting value is changed from the setting value having the lowest advantage. As a result, even if the manager of the game hall unintentionally ends the setting possible situation immediately after the setting possible situation, the setting value has the lowest advantage, so in such a situation It is possible to prevent unintended disadvantages from occurring in the game hall even if the game is performed.

Feature t3. Setting correspondence storage means (setting reference area 341) for storing setting correspondence information corresponding to the setting value set by the setting means,
A selection correspondence storage unit (setting update area 342) for storing selection correspondence information corresponding to the setting value selected in the setting possible state;
Equipped with
The status generation means changes the selection correspondence information stored in the selection correspondence storage means so that the setting value that is a selection target is changed when a change trigger occurs in the setting possible status. (In the forty-ninth embodiment, the function of executing the processing of steps SB307 and SB310 in the main CPU63, in the fifty-third embodiment, the function of executing the processing of step SB908 and step SB914 in the main CPU63),
The setting means stores information corresponding to the selection correspondence information stored in the selection correspondence storage means as the setting correspondence information in the setting correspondence storage means when an ending trigger occurs in the setting possible situation. According to the above, the setting value that was the selection target in the setting possible status is set as the usage target,
The game according to the feature t1 or t2, wherein the start correspondence means stores the selection correspondence information corresponding to the setting value of the start correspondence in the selection correspondence storage means when the setting possible situation is reached. Machine.

According to the feature t3, the setting correspondence storing means for storing the setting correspondence information corresponding to the setting value to be used and the selection correspondence storing means for storing the selection correspondence information corresponding to the setting value being changed in the settable state are provided. By being provided, it becomes possible to change the set value in the settable situation while storing and holding the information of the set value set before the start of the settable situation.

Feature t4. The setting values corresponding to the selection correspondence information stored in the selection correspondence storage means in the settable state are displayed on predetermined display means (first to fourth notification display devices 201 to 204). The gaming machine according to the feature t3, which is provided with a means (a function of executing the processes of steps SA801 to SA803 in the main CPU 63).

According to the feature t4, it is possible to perform the setting value changing operation while confirming the setting value being changed in the settable state.

Feature t5. The display of the set value corresponding to the setting correspondence information stored in the setting correspondence storage means in a situation other than the setting possible situation is displayed on predetermined display means (first to fourth notification display devices 201 to 204). The gaming machine described in the feature t3 or t4, which is provided with a means (a function of executing the processing of step SA601 to step SA603 in the main CPU 63) to be performed.

According to the feature t5, it is possible to confirm the current set value of the target of use, if necessary.

For the configurations of the features t1 to t5, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the above-mentioned characteristic t group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as exemplified above, it is necessary to make the configuration relating to the set value that determines the advantage of the gaming machine suitable, and there is still room for improvement in this respect.

<Feature u group>
Features u1. A first control means (MPU 62),
Second control means (sound-light side MPU 352) that executes control corresponding to the information transmitted by the first control means,
In a gaming machine equipped with
The first control means is
First transmission means (in the 49th embodiment, the main side in the forty-ninth embodiment) that transmits the first start correspondence information (return command at the time of update) based on the fact that the first start situation is reached when the supply of operating power is started. A function of executing the process of step SB314 in the CPU 63, a function of executing the process of step SB918 in the main CPU 63 in the 53rd embodiment),
Second transmission means (49th return command) for transmitting second start correspondence information (return command for confirmation or return command for clear) based on the second start situation when supply of operating power is started. In the fifth embodiment, the function of executing the processing of step SB118 or step SB207 in the main CPU 63, the function of executing the processing of step SB618 in the main CPU 63 in the fifty-first embodiment, and the step of the main CPU63 in the fifty-second embodiment. A function of executing the process of SB725, a function of executing the process of step SB816 in the main CPU 63 in the 53rd embodiment, a function of executing the process of step SC118 in the main CPU 63 in the 54th embodiment),
A gaming machine characterized by being equipped with.

According to the characteristic u1, in the configuration in which the control corresponding to the information transmitted by the first control unit is executed by the second control unit, the first control unit starts the first start when the supply of the operating power is started. The first start correspondence information is transmitted on the basis of the situation, and the second start correspondence information is transmitted on the basis of the second start situation. With this, it is possible to control not only the first control unit but also the second control unit to perform the control corresponding to the type of the start situation when the supply of the operating power is started.

Features u2. The first control means performs a process at the time of starting the supply of the operating power depending on whether the first starting situation or the second starting situation occurs when the supply of the operating power is started (49th embodiment). Steps SB101 to SB122, steps SB601 to SB622 in the fifty-first embodiment, steps SB701 to SB729 in the fifty-second embodiment, steps SB801 to SB818 and steps SB823 to SB826, fifty-third in the fifty-third embodiment. 54 embodiment, at least a part of the processing contents of step SC101 to step SC120 and step SC125 to step SC128) are different from each other, the gaming machine described in the characteristic u1.

According to the characteristic u2, at least a part of the processing at the time of starting the supply of the operating power in the first control means depends on whether it is the first start situation or the second start situation when the supply of the operating power is started. Since the processing contents are different, it is possible for the first control means to execute the processing corresponding to the start situation as the processing when the supply of the operating power is started.

Features u3. The second control means
Start correspondence executing means for executing start correspondence processing regardless of whether the first start correspondence information is received or the second start correspondence information (a positive determination is made in step SB405 in the sound-light side CPU 353). Function),
When the start correspondence information of one of the first start correspondence information and the second start correspondence information is received, a predetermined correspondence process is executed, and the other of the first start correspondence information and the second start correspondence information is executed. A predetermined correspondence executing means (a function of executing the processing of steps SB407, SB409 and SB411 in the sound-light side CPU 353) that does not execute the predetermined correspondence processing when the start correspondence information is received;
The gaming machine according to the feature u1 or u2.

According to the characteristic u3, the second control means executes the start handling process regardless of which of the first start correspondence information and the second start correspondence information is received. It is possible to cause the second control unit to execute the start handling process when the information is transmitted. Further, the second control means executes a predetermined correspondence process when one of the first start correspondence information and the second start correspondence information is received, and performs a predetermined correspondence process when the other start correspondence information is received. Do not execute the corresponding process. With this, it is possible to control not only the first control unit but also the second control unit to perform the control corresponding to the type of the start situation when the supply of the operating power is started.

Features u4. One of the first start situation and the second start situation is that a predetermined start-corresponding operation (RAM clear operation, setting change operation, or setting confirmation operation) is performed when the supply of operating power is started. Occurs based on
The other one of the first start situation and the second start situation occurs based on the fact that the predetermined start corresponding operation is not performed when the supply of the operating power is started, the characteristic u3 Gaming machine described in.

According to the characteristic u4, the content of the control executed not only by the first control means but also by the second control means according to whether or not a predetermined start corresponding operation is performed when the supply of the operating power is started. Can be different.

Features u5. The first control means is a process for controlling the progress of the game after transmitting any start correspondence information among a plurality of types of start correspondence information including the first start correspondence information and the second start correspondence information. (Step S8907 to step S8920) is executed,
The second control means is configured to execute a process (step SB412 to step SB414) corresponding to the progress content of the game after receiving any one of the plurality of types of start correspondence information. The gaming machine according to the characteristic u3 or u4.

According to the characteristic u5, the first control means transmits any start correspondence information before starting the process for controlling the progress of the game, and the second control means after receiving any start correspondence information. A process corresponding to the progress of the game is executed. As a result, the second control means can execute the process corresponding to the progress of the game after the situation where the process for controlling the progress of the game is executed by the first control means. It will be possible. In this case, since the configuration of the characteristic u3 is provided, a plurality of start correspondence information that makes the second control means different in whether or not to execute the predetermined correspondence processing is used to start the processing corresponding to the progress of the game. The trigger can be recognized by the second control means.

Features u6. The first control means is
Means for executing a common handling process in either the first start situation or the second start situation when the supply of operating power is started (49th embodiment) Then, the function of executing the processing of steps SB101 to SB103 in the main CPU 63, the function of executing the processing of steps SB601 to SB603 in the main CPU 63 in the fifty-first embodiment, and the step of the main CPU63 in the fifty-second embodiment. Function for executing the processing of SB701 and step SB702, function for executing the processing of steps SB801 to SB803 in the main CPU 63 in the 53rd embodiment, processing of step SC101 to step SC103 in the main CPU 63 in the 54th embodiment. Function to execute)
When the supply of the operating power is started, the specific handling process is executed based on the one of the first starting situation and the second starting situation, and the supply of the operating power is started. In this case, means for not executing the specific handling process based on the other of the first start situation and the second start situation (in the forty-ninth embodiment, step SB112 in the main CPU 63, step Function for executing the processing of SB115 or step SB117, the function of executing the processing of step SB612, step SB615 or step SB617 in the main CPU 63 in the fifty-first embodiment, step SB711, the step of main CPU63 in the fifty-second embodiment. Function for executing the processing of SB718 or step SB721, function of executing the processing of step SB810, step SB813 or step SB815 in the main CPU 63 in the 53rd embodiment, step SC111, step of the main CPU 63 in the 54th embodiment. SC115 or the function of executing the processing of step SC117),
The gaming machine according to any one of the features u1 to u5.

According to the characteristic u6, the first control means executes the common handling process regardless of whether it is in the first start situation or the second start situation, while the first control situation and the If one of the two start situations is the start situation, the specific handling process is executed. As a result, the common control processing is executed by the first control means regardless of the start status, while the processing corresponding to the type of the start status is executed by the first control means. It becomes possible to do. In this case, the configuration of the characteristic u1 is provided, and the first control means transmits the first start correspondence information based on the fact that the first start situation is set and the first control means transmits the first start correspondence information based on the fact that the second start situation is reached. Since the 2 start correspondence information is transmitted, the control corresponding to the type of the start situation when the supply of the operating power is started can be performed not only by the first control means but also by the second control means. Become.

Features u7. The first control means is
Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (in the forty-ninth embodiment, a function of executing the process of step SB311 in the main CPU 63, In the embodiment, the function of executing the process of step SB915 in the main CPU 63),
Based on the fact that the first setting-related operation (ON operation of the setting key insertion portion 68a and pressing operation of the reset button 68c) was performed when the supply of the operating power was started, the first start situation, First correspondence execution means (in the forty-ninth embodiment, in the main CPU 63 in the forty-ninth embodiment, the first correspondence execution means) is set so that the setting value to be used can be changed (a setting value update process is executed). The function of making an affirmative judgment in step SB114, the function of making an affirmative judgment in step SB614 in the main CPU 63 in the fifty-first embodiment, and the function of making an affirmative judgment in step SB717 in the main CPU63 in the fifty-second embodiment. In the 53rd embodiment, the function of making a positive determination in step SB812 in the main CPU 63, and in the 54th embodiment, the function of making a positive determination in step SC113 of the main CPU 63).
Based on the fact that the second setting-related operation (ON operation of the setting key insertion portion 68a) is performed when the supply of the operating power is started, it is set by the setting means as the second start situation. Second correspondence executing means (function for executing setting confirmation processing in the main CPU 63) for notifying the set value to be used,
The gaming machine according to any one of the features u1 to u6.

According to the characteristic u7, since the setting value to be used is set from the setting values of the plurality of stages corresponding to the advantage of the player, the player is allowed to use the more advantageous setting value. Will be expected. Also, in order to change the setting value to be used, it is necessary to perform the first setting-related operation when the supply of operating power is started, so an act of illegally changing the setting value to be used It is possible to make it difficult to perform. Further, when the supply of operating power is started, the setting value of the usage target is notified by performing the second setting related operation, so that the manager of the game hall confirms the setting value of the usage target as necessary. It becomes possible. In this case, the configuration of the characteristic u1 is provided, and the first control means transmits the first start correspondence information based on the fact that the first start situation is set and the first control means transmits the first start correspondence information based on the fact that the second start situation is reached. Since the 2 start correspondence information is transmitted, it is possible to cause the second control means to perform different control depending on whether the setting is possible or the setting value to be used is notified.

Features u8. The first control means is
Means for executing profit-giving processing in a mode corresponding to a setting value set as a usage target among setting values of a plurality of stages corresponding to the player's advantage (processing of steps S503 and S504 in the main CPU 63) Function to execute)
First correspondence execution means (setting value update processing or setting confirmation in the main CPU 63) that executes predetermined setting-related processing relating to the setting value based on the first start situation when supply of operating power is started Function for executing processing),
Second correspondence execution means (in the 49th embodiment, the main side in the forty-ninth embodiment, which executes another correspondence processing different from the predetermined setting-related processing based on the second start situation when the supply of the operating power is started. A function of the CPU 63 for executing the process of step SB117, a function of the main CPU 63 for executing the process of step SB617 in the fifty-first embodiment, and a function of executing the process of step SB721 for the main CPU63 in the fifty-second embodiment. A function of executing the process of step SB815 in the main CPU 63 in the 53rd embodiment, and a function of executing the process of step SC117 in the main CPU 63 in the 54th embodiment).
The gaming machine according to any one of the features u1 to u7.

According to the characteristic u8, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player can use the more advantageous setting value as the usage target. Will be expected. Further, when the supply of the operating power is started, a predetermined setting-related process relating to the set value is executed based on the first starting status, and when the supply of the operating power is started, the second starting status is obtained. Based on this, another corresponding process different from the predetermined setting-related process is executed. Accordingly, it is possible to cause a case where a predetermined setting-related process is executed and a case where it is not executed depending on the start situation when the supply of the operating power is started. In this case, the configuration of the characteristic u1 is provided, and the first control means transmits the first start correspondence information based on the fact that the first start situation is set and the first control means transmits the first start correspondence information based on the fact that the second start situation is reached. Since the 2 start correspondence information is transmitted, it is possible to cause the second control means to perform different control depending on whether or not the predetermined setting-related processing is executed by the first control means. ..

Features u9. The gaming machine according to feature u8, wherein the second correspondence execution means executes processing for initializing a predetermined storage area provided in the first control means as the different correspondence processing.

According to the characteristic u9, a case where a predetermined setting-related process is executed according to a start situation when the supply of the operating power is started and a case where a predetermined storage area of the first control means is initialized occur. It becomes possible. In this case, the configuration of the characteristic u1 is provided, and the first control means transmits the first start correspondence information based on the fact that the first start situation is set and the first control means transmits the first start correspondence information based on the fact that the second start situation is reached. Since the 2nd start correspondence information is transmitted, different control is performed by the second control means depending on whether the predetermined setting-related processing is executed by the first control means and when the predetermined storage area is initialized. It becomes possible to

Features u10. The second control means
When one of the first start correspondence information and the second start correspondence information is received, the time correspondence information measured by the time measuring means (RTC356) capable of measuring the time is stored as the time correspondence information. Means (RTC memory 357) means for storing (function of executing step SB407 in sound-light side CPU 353 in the forty-ninth embodiment, step SB507 in sound-light side CPU 353 in the fifty embodiment. Function),
A means for executing the time correspondence processing when the processing execution timing is based on the time correspondence information stored in the time correspondence storage means (in the 49th embodiment, the processing of step SB413 in the sound-light side CPU 353 is executed). Function for executing the processing of step SB513 in the sound-light side CPU 353 in the 50th embodiment).
The gaming machine according to any one of the features u1 to u9.

According to the characteristic u10, the second control means executes the time correspondence processing when the processing execution timing is based on the time correspondence information stored in the time correspondence storage means, so that the timing when the predetermined time comes It is possible to execute the time corresponding processing in. In this case, when one of the first start correspondence information and the second start correspondence information is received, the time correspondence information measured by the time measurement means is stored in the time correspondence storage means. As a result, it is possible to select a situation in which the time correspondence information is newly stored in the time correspondence storage means or a situation in which the time correspondence information is not newly stored.

For the configurations of the features u1 to u10, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, Any one or a plurality of configurations of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature v group>
Features v1. Time storage execution means (in the 49th embodiment, the sound-light side in the 49th embodiment) for storing the time correspondence information measured by the time measurement means (RTC356) capable of measuring time in the time correspondence storage means (RTC memory 357). A function of executing the processing of step SB407 in the CPU 353, and a function of executing the processing of step SB507 in the sound-light side CPU 353 in the 50th embodiment).
Time correspondence execution means for executing the time correspondence processing when the processing execution timing is based on the time correspondence information stored in the time correspondence storage means (in the forty-ninth embodiment, in step SB413 of the sound-light side CPU 353). A function of executing processing, in the fiftieth embodiment, a function of executing the processing of step SB513 in the sound-light side CPU 353),
Equipped with
The time storage execution means is in a first start situation when the supply of the operating power is started (in the forty-ninth embodiment, when the power of the pachinko machine 10 is turned on in a situation where no operation is performed, a fiftieth operation is performed). In the embodiment, the time is measured by the time measuring means based on the fact that the RAM clear operation, the setting change operation, or the setting confirmation operation is performed and the pachinko machine 10 is powered on. The time corresponding information is stored in the time corresponding storage means, and when the supply of operating power is started, the second start situation (in the 49th embodiment, a RAM clear operation, a setting change operation, or a setting confirmation operation is performed). When the power of the pachinko machine 10 is turned on in the broken state, in the fiftieth embodiment, the power of the pachinko machine 10 is turned on in the non-operated state). A game machine characterized in that the time correspondence information measured by the time measurement means is not stored in the time correspondence storage means.

According to the feature v1, since the time correspondence processing is executed when the processing execution timing is based on the time correspondence information stored in the time correspondence storage means, the time correspondence processing is executed at the timing when the predetermined time comes. It becomes possible to be executed. In this case, when the first start situation is reached when the supply of the operating power is started, the time correspondence information measured by the time measuring means is stored in the time correspondence storing means, and the supply of the operating power is started. If the second start situation is reached, the time correspondence information is not stored in the time correspondence storage means. As a result, it is possible to select a situation in which the time correspondence information is newly stored in the time correspondence storage means or a situation in which the time correspondence information is not newly stored.

Feature v2. One of the first start situation and the second start situation is that a predetermined start-corresponding operation (RAM clear operation, setting change operation, or setting confirmation operation) is performed when the supply of operating power is started. Occurs based on
The other of the first start situation and the second start situation occurs based on the fact that the predetermined start corresponding operation is not performed when the supply of the operating power is started, the feature v1 Gaming machine described in.

According to the feature v2, depending on whether or not a predetermined start corresponding operation is performed when the supply of the operating power is started, there are a situation in which the time corresponding information is newly stored in the time corresponding storage means and a situation in which the time corresponding information is not newly stored. It becomes possible to select each of the.

Features v3. The second start situation occurs based on a predetermined start-corresponding operation (RAM clear operation, setting change operation, or setting confirmation operation) being performed when the supply of operating power is started,
The gaming machine according to feature v1 or v2, wherein the first start situation occurs based on a fact that the predetermined start corresponding operation is not performed when the supply of operating power is started.

According to the feature v3, when the predetermined start corresponding operation is not performed when the supply of the operating power is started, the time corresponding information is newly stored in the time corresponding storage means, and the supply of the operating power is started. In this case, the time correspondence information is not stored in the time correspondence storage means when a predetermined start correspondence operation is performed. Accordingly, when the supply of the operating power is started, basically, the time correspondence information is newly stored in the time correspondence storage means, and a predetermined start correspondence operation is performed as necessary, so that the time It is possible to prevent the correspondence information from being stored in the time correspondence storage means.

Features v4. When the supply of the operating power is started, the specific handling process is executed based on the one of the first starting situation and the second starting situation, and the supply of the operating power is started. In this case, means for not executing the specific handling process based on the other of the first start situation and the second start situation (in the forty-ninth embodiment, step SB112 in the main CPU 63, step Function for executing the processing of SB115 or step SB117, the function of executing the processing of step SB612, step SB615 or step SB617 in the main CPU 63 in the fifty-first embodiment, step SB711, the step of main CPU63 in the fifty-second embodiment. Function for executing the processing of SB718 or step SB721, function of executing the processing of step SB810, step SB813 or step SB815 in the main CPU 63 in the 53rd embodiment, step SC111, step of the main CPU 63 in the 54th embodiment. The game machine according to any one of features v1 to v3, which is provided with a function of executing processing of SC115 or step SC117.

According to the feature v4, the specific handling process is executed when the start situation is one of the first start situation and the second start situation. In this case, the time correspondence information is newly stored in the time correspondence storage means based on the first start situation and the second start situation according to the feature v1. Correspondence information is not stored in the time correspondence storage means. This makes it possible to associate the presence or absence of execution of the specific correspondence process with the presence or absence of new storage of the time correspondence information.

Features v5. When the supply of the operating power is started, the specific correspondence processing is executed based on the second starting status, and when the supply of the operating power is started, the first starting status is obtained. Means for not executing the specific correspondence process based on the above (a function for executing the process of step SB112, step SB115 or step SB117 in the main CPU 63 in the forty-ninth embodiment, step SB612 in the main CPU63 in the fifty-first embodiment, The function of executing the processing of step SB615 or step SB617, the function of executing the processing of step SB711, step SB718 or step SB721 in the main CPU 63 in the 52nd embodiment, the step SB810 of the main CPU 63 in the 53rd embodiment, Features v1 to v4 having a function of executing the process of step SB813 or step SB815, and a function of executing the process of step SC111, step SC115 or step SC117 in the main CPU 63 in the 54th embodiment. The gaming machine according to any one of 1.

According to the feature v5, the specific handling process is executed when the first start situation and the second start situation are the second start situations. In this case, the time correspondence information is newly stored in the time correspondence storage means based on the first start situation and the second start situation according to the feature v1. Correspondence information is not stored in the time correspondence storage means. This makes it possible to prevent the time correspondence information from being newly stored in the time correspondence storage means when the specific correspondence process is executed.

Features v6. Means for executing a common handling process in either the first start situation or the second start situation when the supply of operating power is started (49th embodiment) A function of executing the processing of steps SB101 to SB103 in the main CPU 63, a function of executing the processing of steps SB601 to SB603 in the main CPU 63 in the 51st embodiment, and a step of the main CPU 63 in the 52nd embodiment. Function for executing the processing of SB701 and step SB702, function for executing the processing of steps SB801 to SB803 in the main CPU 63 in the 53rd embodiment, processing of step SC101 to step SC103 in the main CPU 63 in the 54th embodiment. The game machine according to the feature v4 or v5.

According to the feature v6, the common handling process is executed regardless of whether the first start situation or the second start situation occurs, while the first start situation and the second start situation If the start status is one of them, the specific handling process is executed. As a result, it is possible to execute the common handling process regardless of which start situation, while executing the process corresponding to the type of the start situation.

Features v7. Means for executing profit-giving processing in a mode corresponding to a setting value set as a usage target among setting values of a plurality of stages corresponding to the player's advantage (processing of steps S503 and S504 in the main CPU 63) Function to execute)
Setting-related executing means for executing a predetermined setting-related process relating to the set value when the supply of operating power is started (function for executing a set value update process or a setting confirmation process in the main CPU 63);
Equipped with
The setting-related execution means executes the predetermined setting-related process based on one of the first start situation and the second start situation when the supply of operating power is started. The gaming machine according to any one of the features v1 to v6.

According to the characteristic v7, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player can use the more advantageous setting value as the usage target. Will be expected. Further, when the supply of the operating power is started, the predetermined setting-related processing is executed based on one of the first start situation and the second start situation. This makes it possible to associate the presence/absence of execution of a predetermined setting-related process with the presence/absence of new storage of time correspondence information.

Feature v8. When the supply of the operating power is started, the predetermined storage area provided in the control means is initialized based on one of the first start situation and the second start situation. Means (function of executing step SB117 in the main CPU 63 in the 49th embodiment, function of executing step SB617 in the main CPU 63 in the 51st embodiment, main function of the CPU 63 in the 52nd embodiment) A function of executing the process of step SB721, a function of executing the process of step SB815 in the main CPU 63 in the 53rd embodiment, and a function of executing the process of step SC117 in the main CPU 63 in the 54th embodiment). The gaming machine according to any one of the features v1 to v7.

According to the feature v8, when the supply of the operating power is started, the predetermined storage area of the first control means is initialized based on the one of the first start situation and the second start situation. Be converted. This makes it possible to associate the presence or absence of initialization of the predetermined storage area and the presence or absence of new storage of the time correspondence information.

For the configurations of the features v1 to v8, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the inventions related to the characteristic u group and the characteristic v group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, it is necessary to suitably perform the processing when the supply of the operating power is started, and there is still room for improvement in this respect.

<Feature w group>
Features w1. Predetermined display means (first to fourth notification display devices 201 to 204);
A predetermined display control means (a function for executing a second timer interrupt process in the main CPU 63) for controlling the display of the predetermined display means;
Means for executing profit-giving processing in a mode corresponding to a setting value set as a usage target among setting values of a plurality of stages corresponding to the player's advantage (processing of steps S503 and S504 in the main CPU 63) Function to execute)
Setting-related executing means for executing a predetermined setting-related process relating to the set value when the supply of operating power is started (function for executing a set value update process or a setting confirmation process in the main CPU 63);
Equipped with
The predetermined display control means,
Means for causing the predetermined display means to display the set value when the predetermined setting-related processing is executed (a function of the main CPU 63 for executing the processing of steps S9004 and S9006);
After the predetermined setting-related processing is executed, the check control means (in the thirty-seventh embodiment, mainly used in the thirty-seventh embodiment) that causes the predetermined display means to perform a check display for confirming whether or not the predetermined display means is normal. A function of executing the process of step S9519 in the side CPU 63, a function of executing the process of step SA419 in the main CPU 63 in the 45th embodiment, a function of executing the process of step SA919 in the main CPU 63 in the 46th embodiment, In the forty-ninth embodiment, the main CPU 63 executes the process of step SB123, in the fifty-first embodiment the main CPU63 executes the process of step SB623, and in the fifty-second embodiment the main CPU63 executes step SB712. And a function of executing the process of step SB719, a function of executing the process of step SB817 in the main CPU 63 in the 53rd embodiment, a function of executing the process of step SC119 in the main CPU 63 in the 54th embodiment),
A gaming machine characterized by being equipped with.

According to the feature w1, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player can use the more advantageous setting value as the usage target. Will be expected. Further, when the predetermined setting-related processing is executed, the display regarding the set value is performed on the predetermined display means, so that the manager of the game hall can grasp the current set value by checking the predetermined display means. Becomes Further, by performing the check display on the predetermined display means, it is possible to confirm whether or not the predetermined display means is normal.

In this case, when the supply of the operating power is started, the predetermined display means displays the check display after the predetermined setting-related processing is executed. As a result, the display related to the setting value when the predetermined setting-related processing is executed without the need for the adjustment processing such as ending the check display in the middle when the predetermined setting-related processing is started. Can be prioritized over the check display.

Features w2. The check control unit displays the check display regardless of whether the supply of operating power is started, the predetermined setting-related process is executed, or the predetermined setting-related process is not executed. The gaming machine according to the feature w1, characterized in that the predetermined display means is caused to perform.

According to the characteristic w2, when the supply of the operating power is started, the check display is displayed on the predetermined display means regardless of whether the predetermined setting-related processing is executed. This makes it possible to confirm whether or not the predetermined display means is normal regardless of the situation when the supply of operating power is started.

Features w3. Whether the predetermined setting-related processing is executed or the predetermined setting-related processing is not executed as the supply start processing executed when the supply of the operating power is started A process that is commonly executed, and when the predetermined setting-related process is executed, a common process that is a process whose execution order is later than the predetermined setting-related process is set,
The gaming machine according to the feature w1 or w2, wherein a process for starting the check display on the predetermined display means is set as the common process.

According to the feature w3, when the supply of the operating power is started, the check display is displayed on the predetermined display means regardless of whether the predetermined setting-related processing is executed. This makes it possible to confirm whether or not the predetermined display means is normal regardless of the situation when the supply of operating power is started. Further, since the process for starting the check display on the predetermined display means is set as the common process, it is possible to achieve the excellent effect as described above while simplifying the process configuration.

Features w4. A means for executing processing for advancing the game after the supply of the operating power is started and the processing at the start of the supply is completed (function of executing the processing of steps S8907 to S8920 in the main CPU 63),
The gaming machine according to any one of features w1 to w3, wherein processing for advancing the game can be started even in a situation where the check display is being executed on the predetermined display means. ..

According to the feature w4, the process for advancing the game can be started even in the situation where the check display on the predetermined display means is being executed. Therefore, the check is performed on the predetermined display means after the predetermined setting-related processing is executed. It is possible to prevent the start timing of the process for advancing the game from being delayed even when the message is displayed.

Features w5. When the supply of the operating power is started, the delay execution means for executing the delay processing that allows the start of the processing for advancing the game to be delayed (the processing of steps SB715 and SB724 in the main CPU 63 is executed). Function),
The check control means causes the predetermined display means to start the check display before the delay processing is started when the predetermined setting-related processing is not executed when the supply of the operating power is started. The gaming machine according to any one of the features w1 to w4.

According to the feature w5, when the supply of the operating power is started, the delay process that allows the start of the process for advancing the game to be delayed is executed, thereby completing the initial setting of various devices. It is possible to start the process for advancing the game later. In this case, if the predetermined setting-related processing is not executed when the supply of the operating power is started, the check display on the predetermined display means is started before the delay processing is started. As a result, it is possible to perform the check display using the period in which the start of the process for advancing the game is delayed.

Features w6. The gaming machine according to feature w5, wherein the delay executing means does not execute the delay process when the predetermined setting-related process is executed.

According to the feature w6, since a predetermined period is required when the predetermined setting-related processing is executed, it is possible to complete the initial setting of various devices before the processing for advancing the game is started. Become. In this case, when the predetermined setting-related processing is executed, the delay processing is not executed, so that the start of the processing for advancing the game in the situation where the predetermined setting-related processing is executed is extremely extreme. It's possible to avoid being late.

Features w7. The setting related execution means,
Change of the setting value to be used based on the fact that the first setting-related operation (ON operation of the setting key insertion portion 68a and pressing operation of the reset button 68c) is performed when the supply of operating power is started. Status generating means (a function for making an affirmative determination in step SB114 in the main CPU 63 in the forty-ninth embodiment; In the fifty-first embodiment, the function of making a positive decision in step SB614 in the main CPU63, in the fifty-second embodiment, the function of making a positive decision in step SB717 in the main CPU63, in the fifty-third embodiment, in the main CPU63 A function to make an affirmative judgment in SB812, a function to make an affirmative judgment in step SC113 in the main CPU 63 in the 54th embodiment),
Notification generation that notifies the setting value to be used based on the fact that the second setting-related operation (ON operation of the setting key insertion portion 68a) is performed when supply of operating power is started Means (a function of executing setting confirmation processing in the main CPU 63),
The gaming machine according to any one of the features w1 to w6.

According to the feature w7, in order to change the setting value to be used, it is necessary to perform the first setting-related operation when the supply of the operating power is started, so the setting value to be used is illegally changed. It becomes possible to make it difficult to perform the intended action. Further, when the supply of operating power is started, the setting value of the usage target is notified by performing the second setting related operation, so that the manager of the game hall confirms the setting value of the usage target as necessary. It becomes possible.

Features w8. The predetermined display control means is provided with means for displaying information corresponding to the management result of the game history on the predetermined display means (function of executing the processes of steps S8708, S8709 and S9107 in the main CPU 63). The gaming machine according to any one of features w1 to w7.

According to the feature w8, it becomes possible to notify the manager of the game hall of the management result of the game history. In this case, whether or not information corresponding to the management result of the game history on the predetermined display means is accurately displayed by providing the check display on the predetermined display means with the configuration of the characteristic w1. It becomes possible to confirm.

In addition, with respect to the configuration of the features w1 to w8, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature x group>
Feature x1. Predetermined display means (first to fourth notification display devices 201 to 204);
A predetermined display control means (a function for executing a second timer interrupt process in the main CPU 63) for controlling the display of the predetermined display means;
A means for executing a process for advancing a game after the supply of the operating power is started and the situation after the start of the supply is completed (a function of the main CPU 63 for executing the processes of steps S8907 to S8920),
Equipped with
The predetermined display control means causes the predetermined display means to perform a check display for confirming whether or not the predetermined display means is normal in the post-supply start situation (36th embodiment). A function of executing the process of step S9405 in the main CPU 63, and a function of executing the processes of step SB713 and step SB722 in the main CPU 63 in the 52nd embodiment).
In a situation where the check display is being performed on the predetermined display means, a delay situation that allows delaying the start of the process for advancing the game (in the 36th embodiment, a negative determination is made in step S9406). The game machine is characterized by a situation in which the processing of Steps SB715 and SB724 is being executed by the main CPU 63 in the 52nd embodiment).

According to the feature x1, when the supply of the operating power is started, the check display is displayed on the predetermined display means, so that it is possible to confirm whether or not the predetermined display means is normal. In this case, in the situation where the check display is being performed, there may occur a delay situation in which it is possible to delay the start of the process for advancing the game. This makes it possible to secure an opportunity to confirm the check display on the predetermined display means before the process for advancing the game is started. Further, due to the occurrence of the delay situation, it is possible to complete the initial setting of various devices before the processing for advancing the game is started. Then, it is possible to make a check display on the predetermined display means by utilizing this delay state.

Feature x2. Means for setting the delay status when the check display is being performed on the predetermined display means (in the thirty-sixth embodiment, the main CPU 63 executes the process of step S9406, the fifty-second embodiment). In the form, the gaming machine described in the feature x1 is provided with a function of executing the processes of step SB715 and step SB724 in the main CPU 63).

According to the feature x2, since the check display is in a delayed state, the process for advancing the game should not be started while the check display is being performed. Is possible.

Feature x3. When the supply of the operating power is started, the delay state is set in the situation where the check display is being performed on the predetermined display means based on the first starting situation, and the supply of the operating power is started. In this case, the gaming machine according to the feature x1 or x2 is characterized in that the delay state does not occur in the situation where the check display is being performed on the predetermined display means based on the second start situation.

According to the characteristic x3, in the case where the first display situation is the first display situation, the game is progressed while the check display is being performed due to the delay situation when the check display is being performed by the predetermined display means. It is possible to prevent the processing for starting from being started, and in the case of the second start situation, it is possible to prevent the delay situation in the situation where the check display is being performed by the predetermined display means. It is possible to prevent the start timing of the processing for advancing the game from being extremely delayed.

Feature x4. Means for executing profit-giving processing in a mode corresponding to a setting value set as a usage target among setting values of a plurality of stages corresponding to the player's advantage (processing of steps S503 and S504 in the main CPU 63) Function to execute)
Setting-related executing means for executing a predetermined setting-related process relating to the set value when the supply of operating power is started (function for executing a set value update process or a setting confirmation process in the main CPU 63);
Equipped with
The first start situation is a situation in which the predetermined setting-related processing is not executed in the situation after the start of supply,
The gaming machine according to feature x3, wherein the second start situation is a situation in which the predetermined setting-related processing is executed in the post-supply start situation.

According to the characteristic x4, since a predetermined period is required when the predetermined setting related processing is executed, it is possible to complete the initial setting of various devices before the processing for advancing the game is started. Become. In this case, when the predetermined setting-related processing is executed, the predetermined setting-related processing is executed by preventing the delay state from occurring in the situation where the check display is being displayed on the predetermined display means. It is possible to prevent the start of processing for advancing a game from being extremely delayed in a situation.

Feature x5. The setting related execution means,
Change of the setting value to be used based on the fact that the first setting-related operation (ON operation of the setting key insertion portion 68a and pressing operation of the reset button 68c) is performed when the supply of operating power is started. Status generating means (a function for making an affirmative determination in step SB114 in the main CPU 63 in the forty-ninth embodiment; In the fifty-first embodiment, the function of making a positive decision in step SB614 in the main CPU63, in the fifty-second embodiment, the function of making a positive decision in step SB717 in the main CPU63, in the fifty-third embodiment, in the main CPU63 A function to make an affirmative judgment in SB812, a function to make an affirmative judgment in step SC113 in the main CPU 63 in the 54th embodiment),
Notification generation that notifies the setting value to be used based on the fact that the second setting-related operation (ON operation of the setting key insertion portion 68a) is performed when supply of operating power is started Means (a function of executing setting confirmation processing in the main CPU 63),
A gaming machine according to feature x4, characterized by comprising:

According to the feature x5, in order to change the setting value to be used, it is necessary to perform the first setting-related operation when the supply of the operating power is started, so the setting value to be used is illegally changed. It becomes possible to make it difficult to perform the intended action. Further, when the supply of operating power is started, the setting value of the usage target is notified by performing the second setting related operation, so that the manager of the game hall confirms the setting value of the usage target as necessary. It becomes possible.

Feature x6. The predetermined display control means is provided with means for displaying information corresponding to the management result of the game history on the predetermined display means (function of executing the processes of steps S8708, S8709 and S9107 in the main CPU 63). The gaming machine according to any one of the features x1 to x5.

According to the feature x6, it becomes possible to inform the manager of the game hall of the management result of the game history. In this case, whether or not the information corresponding to the management result of the game history on the predetermined display means is accurately displayed by providing the check display on the predetermined display means with the configuration of the above feature x1. It becomes possible to confirm.

In addition, with respect to the configuration of the features x1 to x6, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the characteristic w group and the characteristic x group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine such as the above example, a configuration capable of confirming whether or not the display on the predetermined display means is accurately performed is required, and there is still room for improvement in this respect. is there.

<Characteristic y group>
Feature y1. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (in the forty-ninth embodiment, a function of executing the process of step SB311 in the main CPU 63, In the embodiment, the function of executing the process of step SB915 in the main CPU 63),
A status generating unit (in the forty-ninth embodiment, step SB114 in the main CPU 63 in the forty-ninth embodiment) that sets a status in which the setting value to be used can be changed (a setting value updating process is executed). Function for making an affirmative judgment in the 51st embodiment, a function for making an affirmative judgment in step SB614 in the main CPU 63 in the 51st embodiment, and a function for making an affirmative judgment in step SB717 in the main CPU 63 in the 52nd embodiment; In the embodiment, the function of making an affirmative judgment in step SB812 in the main CPU 63, and the function of making an affirmative judgment in step SC113 in the main CPU 63 in the 54th embodiment).
A setting monitoring unit that executes a setting monitoring process for monitoring whether or not the setting value of the usage target is abnormal (in the forty-ninth embodiment, a function of executing the process of step SB106 in the main CPU 63, the fifty-first embodiment). In the embodiment, the function of executing the process of step SB606 in the main CPU 63, in the 52nd embodiment, the function of executing the process of step SB705 in the main CPU 63, and in the 53rd embodiment, the process of step SB806 in the main CPU 63. A function to execute, a function to execute the process of step SC106 in the main CPU 63 in the 54th embodiment),
Equipped with
The process at the start of supply performed when the supply of the operating power to the control unit having the setting unit is started (step SB101 to step SB122 in the forty-ninth embodiment, step SB601 to step in the fifty-first embodiment). SB622, step SB701 to step SB729 in the 52nd embodiment, step SB801 to step SB818 and step SB823 to step SB826 in the 53rd embodiment, step SC101 to step SC120 and step SC125 to step SC128 in the 54th embodiment). A gaming machine characterized in that the setting monitoring process is included in.

According to the characteristic y1, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the degree of advantage of the player, the player can set the more advantageous setting value as the usage target. Will be expected. Further, since the setting monitoring process for monitoring whether or not the setting value of the usage target is abnormal is performed, it is possible to deal with it when the setting value of the usage target is abnormal. In addition, since the setting monitoring process is included in the process at the start of supply, it is possible to prevent the process for advancing the game from being started even if the setting value to be used is abnormal. Becomes

Feature y2. The gaming machine according to feature y1, wherein the setting monitoring unit executes the setting monitoring process each time a monitoring trigger occurs even after the process at the start of supply is completed.

According to the feature y2, since the setting monitoring process is executed every time the monitoring trigger occurs after the process at the start of supply is completed, it is easy to identify that the setting value to be used is abnormal.

Feature y3. A means for executing an interrupt process that is regularly activated (a function for executing a first timer interrupt process in the main CPU 63),
The gaming machine according to feature y2, wherein the interrupt monitoring process includes the setting monitoring process.

According to the feature y3, since the setting monitoring process is executed every time it is activated, it is possible to increase the frequency of monitoring whether or not the setting value to be used is abnormal.

Feature y4. The setting monitoring means sets a restricted state in which execution of a predetermined progress process for advancing a game is restricted based on the fact that the setting value of the use target is specified to be abnormal in the setting monitoring process. Restricting Means (Function of Performing Step SB119 in Main CPU 63 in 49th Embodiment, Function of Performing Step SB619 in Main CPU 63 in 51st Embodiment, Main CPU 63 in 52nd Embodiment) A function of executing the process of step SB726 in the 53rd embodiment, a function of executing the process of step SB823 in the main CPU 63 in the 53rd embodiment, and a function of executing the process of step SC125 in the main CPU 63 in the 54th embodiment). The gaming machine according to any one of the features y1 to y3.

According to the characteristic y4, when it is specified that the set value of the use target is abnormal, the execution of the predetermined progress processing for advancing the game is restricted, so that the set value of the use target is also abnormal. Regardless, it is possible to prevent the game from being started.

Feature y5. Means for releasing the restricted state based on the occurrence of the settable state (a function for executing the process of step SB303 in the main CPU 63 in the 49th embodiment, step SB904 in the main CPU 63 in the 53rd embodiment). The game machine according to feature y4, which is provided with a function of executing the process of.

According to the feature y5, it is possible to make a new setting of the set value of the use target when canceling the situation where the set value of the use target is abnormal.

Feature y6. The feature y4 or y5 is characterized in that the regulation means brings the regulation state into the regulation state when the supply of the operation power is resumed even if the supply of the operation power is stopped in the situation of the regulation state. Gaming machine described in.

According to the characteristic y6, it is possible to prevent the state in which the execution of the predetermined progress processing is restricted due to the abnormal setting value of the use target from being canceled only by stopping the supply of the operating power.

Feature y7. Features y4 to y4 characterized by including a unit (a function of executing the processes of steps S8901 to S8905 in the main CPU 63) that executes a non-regulation process different from the predetermined progress process even in the restriction state. The gaming machine according to any one of y6.

According to the feature y7, it is possible to execute the non-restriction process even in the situation where the execution of the predetermined progress process is restricted due to the abnormal setting value of the use target. As a result, it becomes possible to ensure the execution of the required processing even in the restricted state.

Feature y8. The gaming machine according to feature y7, wherein the non-restriction process includes a power failure monitoring process (step S8901) for monitoring occurrence of a power failure.

According to the feature y8, the power outage monitoring process is executed even in the regulated state, so that when the power outage occurs in the regulated state, it is possible to appropriately cope with the power outage.

Feature y9. Based on the fact that the setting monitoring means identifies that the setting value of the use target is abnormal in the setting monitoring process, a notification is made to enable the player to recognize that the setting possible situation should be generated. Means to be executed (function of executing step SB121 in the main CPU 63 in the 49th embodiment, function of executing step SB621 in the main CPU 63 in the 51st embodiment, 52nd embodiment In the embodiment, the function of executing the process of step SB728 in the main CPU 63, in the 53rd embodiment, the function of executing the process of step SB825 in the main CPU 63, and in the 54th embodiment, the process of step SC127 in the main CPU 63 is executed. A gaming machine according to any one of the features y1 to y8.

According to the feature y9, when it is specified that the setting value of the use target is abnormal, a notification is made to enable the player to recognize that the settable situation should be generated, and thus the use target setting is performed. When the value becomes abnormal, it is possible to urge the manager of the game hall to cancel it.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features y1 to y9. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the characteristic y group, it is possible to solve the following problems.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, it is necessary to appropriately manage the setting value that determines the advantage of the gaming machine, and there is still room for improvement in this respect.

<Feature z group>
Feature z1. Predetermined monitoring means for monitoring whether or not a predetermined abnormality has occurred with respect to information stored in a predetermined storage area (work area 221 for specific control) when supply of operating power is started (thirty-third embodiment). Then, the function of the main CPU 63 to execute the processing of steps S7906 and S7909, the function of the main CPU 63 to execute the processing of steps S8807 and S8810 in the 35th embodiment, and the step of the main CPU 63 in the 36th embodiment. A function of executing the processing of S9408 and step S9411, a function of executing the processing of steps S9506 and S9509 in the main CPU 63 in the 37th embodiment, and a processing of steps S9905 and S9908 in the main CPU 63 in the 42nd embodiment. Function for executing the processing of steps SA406 and SA409 in the main CPU 63 in the 45th embodiment, and the function of executing the processing of step SA907 and step SA910 in the main CPU 63 in the 46th embodiment, In the forty-ninth embodiment, the function of executing the processes of steps SB104 to SB106 in the main CPU 63, in the fifty-first embodiment, the function of executing the processes of step SB604 to step SB606 in the main CPU63, and in the fifty-second embodiment, the main The function of executing the processing of steps SB703 to SB705 in the side CPU 63, the function of executing the processing of steps SB804 to SB806 in the main CPU 63 in the 53rd embodiment, and the step SC104 of the main CPU 63 in the 54th embodiment. A function of executing the processing of step SC106),
Based on the fact that the predetermined abnormality has been identified by the predetermined monitoring means, the restriction means is set to a restriction state in which execution of the predetermined progress processing for advancing the game is restricted (third embodiment). Then, the main CPU 63 executes the process of step S7910, the 35th embodiment executes the process of step S8811 in the main CPU 63, and the 36th embodiment executes the process of step S9412 in the main CPU 63. Function, a function of the main CPU 63 that executes the process of step S9510 in the 37th embodiment, a function of the main CPU 63 that executes the process of step S9909 in the 42nd embodiment, and a main CPU 63 of the 45th embodiment. A function of executing the process of step SA410, a function of executing the process of step SA911 in the main CPU 63 in the 46th embodiment, a function of executing the process of step SB119 in the main CPU 63 in the 49th embodiment, the 51st In the 52nd embodiment, the main CPU 63 executes the process of step SB619 in the main CPU 63, in the 52nd embodiment, the main CPU 63 executes the process of step SB726, and in the 53rd embodiment the main CPU 63 executes the process of step SB823. A function to execute, a function to execute the process of step SC125 in the main CPU 63 in the 54th embodiment),
Means for executing non-restriction processing different from the predetermined progress processing even in the restricted state (function of executing processing of steps S8201 to S8206 in the main CPU 63 in the thirty-third embodiment, in the thirty-fifth embodiment A function of executing the processing of steps S8901 to S8905 in the main CPU 63, and a function of executing the processing of steps SA101 to SA106 in the main CPU 63 in the 42nd embodiment).
A gaming machine characterized by being equipped with.

According to the characteristic z1, when it is specified that a predetermined abnormality has occurred with respect to the information stored in the predetermined storage area, the execution of the predetermined progression process for advancing the game is restricted, so that the predetermined abnormality occurs. It is possible to prevent the game from starting even though it has occurred. Further, even when the execution of the predetermined progress processing is restricted due to the occurrence of the predetermined abnormality, the non-restriction processing can be executed. As a result, it becomes possible to ensure the execution of the required processing even in the restricted state.

Feature z2. The non-regulation processing includes a power failure monitoring processing for monitoring occurrence of power failure (step S8201 in the 33rd embodiment, step S8901 in the 35th embodiment, step SA102 in the 42nd embodiment). The gaming machine according to feature z1 characterized by being present.

According to the feature z2, the power outage monitoring process is executed even in the regulated state, so that when the power outage occurs in the regulated state, it is possible to appropriately cope with the power outage.

Feature z3. The feature z1 or z2 is characterized in that the regulation means brings the regulation state into the regulation state when the supply of the operation power is resumed even if the supply of the operation power is stopped in the situation of the regulation state. Gaming machine described in.

According to the characteristic z3, it is possible to prevent the state in which the execution of the predetermined progress processing is restricted due to the occurrence of the predetermined abnormality from being canceled only by stopping the supply of the operating power.

Feature z4. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (in the forty-ninth embodiment, a function of executing the process of step SB311 in the main CPU 63, In the embodiment, the function of executing the process of step SB915 in the main CPU 63),
A status generating unit (in the forty-ninth embodiment, step SB114 in the main CPU 63 in the forty-ninth embodiment) that sets a status in which the setting value to be used can be changed (a setting value updating process is executed). Function for making an affirmative judgment in the 51st embodiment, a function for making an affirmative judgment in step SB614 in the main CPU 63 in the 51st embodiment, and a function for making an affirmative judgment in step SB717 in the main CPU 63 in the 52nd embodiment; In the embodiment, the function of making an affirmative judgment in step SB812 in the main CPU 63, and the function of making an affirmative judgment in step SC113 in the main CPU 63 in the 54th embodiment).
The gaming machine according to any one of features z1 to z3, characterized in that

According to the characteristic z4, since the setting value to be used is set from the setting values of the plurality of stages corresponding to the advantage of the player, the player can set the more advantageous setting value as the usage target. Will be expected. In this case, if a predetermined abnormality has occurred with respect to the information stored in the predetermined storage area, there is a possibility that an abnormality has also occurred with respect to the set value. On the other hand, with the configuration of the characteristic z1 and when it is specified that a predetermined abnormality has occurred with respect to the information stored in the predetermined storage area, execution of the predetermined progress processing for advancing the game is restricted. Therefore, it is possible to prevent the game from being started even though an abnormality may have occurred with respect to the set value.

Feature z5. Means for executing a notification for making it possible for the player to recognize that the settable condition should be generated based on the fact that the predetermined abnormality has been identified by the predetermined monitoring means ( In the forty-ninth embodiment, the main CPU 63 executes the process of step SB121, in the fifty-first embodiment the main CPU63 executes the process of step SB621, and in the fifty-second embodiment the main CPU63 executes step SB728. The function of executing the process of step SB825 in the main CPU 63 in the 53rd embodiment, and the function of executing the process of step SC127 in the main CPU 63 in the 54th embodiment). The gaming machine according to feature z4.

According to the characteristic z5, when it is specified that the predetermined abnormality has occurred, a notification is made to enable the player to recognize that the setting-possible situation should be generated. It is possible to prompt the manager of the game hall to set the set value.

Feature z6. Means for releasing the restricted state based on the occurrence of the settable state (a function for executing the process of step SB303 in the main CPU 63 in the 49th embodiment, step SB904 in the main CPU 63 in the 53rd embodiment). The game machine according to the feature z4 or z5, characterized in that it has a function of executing the processing of.

According to the feature z6, it is possible to make a new setting of the setting value to be used when canceling the situation where the predetermined abnormality has occurred.

In addition, with respect to the configurations of the features z1 to z6, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4, features Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αA group>
Features αA1. Predetermined monitoring means for monitoring whether or not a predetermined abnormality has occurred with respect to information stored in a predetermined storage area (work area 221 for specific control) when supply of operating power is started (49th embodiment). A function of executing the processing of steps SB104 to SB106 in the main CPU 63, a function of executing the processing of steps SB604 to SB606 in the main CPU 63 in the fifty-first embodiment, and a step of main CPU63 in the fifty-second embodiment. Function for executing the processing of SB703 to step SB705, function of executing the processing of step SB804 to step SB806 in the main CPU 63 in the 53rd embodiment, processing of step SC104 to step SC106 in the main CPU 63 in the 54th embodiment. Function to execute)
When the predetermined monitoring unit determines that the predetermined abnormality has occurred, the execution content of the process at the start of supplying the operating power is determined by the predetermined monitoring unit to have the predetermined abnormality. Restriction means for making the execution content different from the case of not performing (a function of executing the process of step SB119 in the main CPU 63 in the 49th embodiment, a process of step SB619 in the main CPU 63 in the 51st embodiment. Function to be executed, function to execute the process of step SB726 in the main CPU 63 in the 52nd embodiment, function to execute the process of step SB823 in the main CPU 63 in the 53rd embodiment, main part in the 54th embodiment A function of executing the processing of step SC125 in the CPU 63),
Specific output means for performing a specific output to the outside of the gaming machine based on the fact that the predetermined abnormality has been specified by the predetermined monitoring means (in the forty-ninth embodiment, the process of step SB122 in the main CPU 63). Function for executing step SB622 in the main CPU 63 in the 51st embodiment, function for executing step SB729 in the main CPU 63 in the 52nd embodiment, main function in the 53rd embodiment A function of executing the processing of step SB826 in the side CPU 63, and a function of executing the processing of step SC128 in the main CPU 63 in the 54th embodiment).
A gaming machine characterized by being equipped with.

According to the characteristic αA1, when it is specified that the predetermined abnormality has occurred with respect to the information stored in the predetermined storage area, when the execution content of the process at the start of supplying the operating power does not have the predetermined abnormality Since the execution content is different from that, it is possible to prevent the processing from proceeding normally even if the predetermined abnormality has occurred. Further, the specific output is performed outside the gaming machine based on the fact that the predetermined abnormality has been identified. Thereby, it becomes possible to urge the manager of the game hall to deal with the occurrence of the predetermined abnormality.

Features αA2. The gaming machine according to feature αA1, wherein the specific output means outputs the specific output to the outside of the gaming machine even when it is specified that an event different from the predetermined abnormality is occurring.

According to the feature αA2, the specific output is performed outside the gaming machine even when an event different from the predetermined abnormality occurs. As a result, it is possible to combine the configuration for performing the specific output.

Features αA3. Even if the supply of the operating power is stopped in the situation where the predetermined abnormality is occurring, the specific output means is the gaming machine if the predetermined abnormality occurs when the supply of the operating power is resumed. The gaming machine according to the feature αA1 or αA2, which is characterized in that the specific output is performed externally.

According to the characteristic αA3, it is possible to perform the specific output to the outside of the gaming machine each time the supply of the operating power is restarted in the situation where the predetermined abnormality occurs. This makes it easier for the manager of the game hall to recognize that the predetermined abnormality has occurred.

Features αA4. The restriction means sets a restriction state in which execution of predetermined progress processing for advancing a game is restricted based on the fact that the predetermined abnormality has been identified by the predetermined monitoring means. The gaming machine according to any one of the features αA1 to αA3.

According to the characteristic αA4, when it is specified that the predetermined abnormality has occurred with respect to the information stored in the predetermined storage area, the execution of the predetermined progression process for advancing the game is restricted, so that the predetermined abnormality occurs. It is possible to prevent the game from starting even though it has occurred.

Features αA5. Means for executing non-restriction processing different from the predetermined progress processing even in the restricted state (function of executing processing of steps S8201 to S8206 in the main CPU 63 in the thirty-third embodiment, in the thirty-fifth embodiment A feature αA4 characterized in that the main CPU 63 has a function of executing the processes of steps S8901 to S8905, and in the 42nd embodiment, the main CPU 63 has a function of executing the processes of steps SA101 to SA106). The game machine described.

According to the characteristic αA5, the non-restriction process can be executed even in the situation where the execution of the predetermined progress process is restricted due to the occurrence of the predetermined abnormality. As a result, it becomes possible to ensure the execution of the required processing even in the restricted state.

Features αA6. The non-regulation processing includes a power failure monitoring processing for monitoring occurrence of power failure (step S8201 in the 33rd embodiment, step S8901 in the 35th embodiment, step SA102 in the 42nd embodiment). The gaming machine described in the feature αA5.

According to the feature αA6, the power outage monitoring process is executed even in the regulated state, so that when the power outage occurs in the regulated state, it is possible to appropriately cope with the power outage.

Features αA7. Features αA4 to αA6 characterized in that the regulation means brings the regulation state into the regulation state when the supply of the operation power is resumed even if the supply of the operation power is stopped in the situation of the regulation state. The gaming machine according to any one of 1.

According to the characteristic αA7, it is possible to prevent the state in which the execution of the predetermined progress processing is restricted due to the occurrence of the predetermined abnormality from being canceled only by stopping the supply of the operating power.

Features αA8. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (in the forty-ninth embodiment, a function of executing the process of step SB311 in the main CPU 63, In the embodiment, the function of executing the process of step SB915 in the main CPU 63),
A status generating unit (in the forty-ninth embodiment, step SB114 in the main CPU 63 in the forty-ninth embodiment) that sets a status in which the setting value to be used can be changed (a setting value updating process is executed). Function for making an affirmative judgment in the 51st embodiment, a function for making an affirmative judgment in step SB614 in the main CPU 63 in the 51st embodiment, and a function for making an affirmative judgment in step SB717 in the main CPU 63 in the 52nd embodiment; In the embodiment, the function of making an affirmative judgment in step SB812 in the main CPU 63, and the function of making an affirmative judgment in step SC113 in the main CPU 63 in the 54th embodiment).
The gaming machine according to any one of the features αA4 to αA7.

According to the characteristic αA8, the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, so that the player can set the more advantageous setting value as the usage target. Will be expected. In this case, if a predetermined abnormality has occurred with respect to the information stored in the predetermined storage area, there is a possibility that an abnormality has also occurred with respect to the set value. On the other hand, when it is specified that a predetermined abnormality has occurred with respect to the information stored in the predetermined storage area, which has the configuration of the characteristic αA1, the execution content of the process at the start of the supply of the operating power is predetermined. Since the execution content is different from that when there is no error, it is possible to prevent the process from proceeding normally even though an error may have occurred regarding the set value. Become. In addition, since a specific output is performed outside the gaming machine based on the fact that a predetermined abnormality has been identified, it is possible to deal with the possibility that an abnormality may have occurred with respect to the set value. It is possible to urge the manager of the hall.

Features αA9. Means for executing a notification for making it possible for the player to recognize that the settable condition should be generated based on the fact that the predetermined abnormality has been identified by the predetermined monitoring means ( In the forty-ninth embodiment, the main CPU 63 executes the process of step SB121, in the fifty-first embodiment the main CPU63 executes the process of step SB621, and in the fifty-second embodiment the main CPU63 executes step SB728. The function of executing the process of step SB825 in the main CPU 63 in the 53rd embodiment, and the function of executing the process of step SC127 in the main CPU 63 in the 54th embodiment). The gaming machine according to feature αA8.

According to the characteristic αA9, when it is specified that the predetermined abnormality has occurred, a notification is made to enable the player to recognize that the setting-possible situation should be generated. It is possible to prompt the manager of the game hall to set the set value.

Feature αA10. The restricting means restricts execution of a predetermined advancing process for advancing a game based on the fact that the predetermined abnormality has been identified by the predetermined monitoring means. ,
This gaming machine is means for canceling the restricted state based on the occurrence of the settable condition (a function for executing the process of step SB303 in the main CPU 63 in the forty-ninth embodiment, a main function in the fifty-third embodiment). The game machine according to feature αA8 or αA9, which is provided with a function of executing the processing of step SB904 in the side CPU 63.

According to the characteristic αA10, it is possible to make a new setting of the set value to be used when canceling the situation in which the predetermined abnormality has occurred.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features αA1 to αA10. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, and features βA1 to βA. 4. Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αB group>
Feature αB1. A means for starting the process at the time of starting the supply of the operating power when the supply of the operating power is started (steps SB101 to SB122 in the forty-ninth embodiment, step SB601 to step SB622 in the fifty-first embodiment, step 52). Step SB701 to Step SB729 in the embodiment, Step SB801 to Step SB818 and Step SB823 to Step SB826 in the 53rd embodiment, Step SC101 to Step SC120 and Step SC125 to Step SC128 in the 54th embodiment, and
Means for executing interrupt processing that is activated periodically (function for executing first timer interrupt processing in the main CPU 63);
Means for executing profit-giving processing in a mode corresponding to a setting value set as a usage target among setting values of a plurality of stages corresponding to the player's advantage (processing of steps S503 and S504 in the main CPU 63) Function to execute)
As a part of the processing at the start of the supply of the operating power, a setting-related executing means for executing a predetermined setting-related processing relating to the setting value (a function for executing the setting value updating processing or the setting confirmation processing in the main CPU 63). )When,
Permission setting means for setting a state in which the execution of the interrupt processing is prohibited to a state in which the execution of the interrupt processing is permitted when the predetermined setting-related processing is executed in the processing when the supply of the operating power is started. (A function of executing the processing of step SB201 or step SB301 in the main CPU 63 in the 49th embodiment, a function of executing the processing of step SB901 in the main CPU 63 in the 53rd embodiment),
A gaming machine characterized by being equipped with.

According to the characteristic αB1, the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, so that the player can use the more advantageous setting value as the usage target. Will be expected. Further, since the predetermined setting-related processing relating to the set value is executed as a part of the processing at the time of starting the supply of the operating power, it is possible to make it difficult to carry out the act of illegally executing the predetermined setting-related processing. It will be possible.

In this case, when a predetermined setting-related process is executed in the process at the time of starting the supply of the operating power, the execution of the interrupt process is changed from the prohibited state to the permitted state. That is, basically, the execution of the interrupt process is prohibited in the process at the start of supplying the operating power, while the interrupt process can be interrupted and activated in the predetermined setting-related process. By basically prohibiting the execution of the interrupt process in the process at the start of supplying the operating power, it is possible to shorten the time required to complete the process at the start of supplying the operating power. On the other hand, since the process related to the setting value is executed in the predetermined setting-related process, it is expected that the time required to complete the process will be long. In such a situation where the predetermined setting-related process is executed, By permitting the execution of the interrupt processing, it becomes possible to optimize the processing execution mode.

Feature αB2. The gaming machine according to feature αB1, wherein the setting-related executing means ends the predetermined setting-related processing on the basis of an end trigger operation being performed in the predetermined setting-related processing.

According to the characteristic αB2, the predetermined setting-related process is continued until the end trigger operation is performed, and therefore the time required for the process to be completed tends to be long. In this case, since the configuration of the characteristic αB1 is provided and the execution of the interrupt process is permitted in the situation where the predetermined setting-related process is executed, the execution mode of the process can be made suitable. ..

Feature αB3. When the predetermined setting-related processing ends, the prohibition setting means (in the forty-ninth embodiment, the main CPU 63 in the main CPU 63 in the forty-ninth embodiment, sets the state in which the execution of the interrupt processing is permitted to the state in which execution of the interrupt processing is prohibited The gaming machine described in the feature αB1 or αB2, which is provided with a function of executing the process of step SB206 or step SB312, and a function of executing the process of step SB916 in the main CPU 63 in the 53rd embodiment.

According to the characteristic αB3, the execution of the interrupt process is prohibited again when the predetermined setting-related process ends. As a result, it is possible to limit the period during which the execution of the interrupt process is permitted to the period during which the predetermined setting-related process is executed in the situation where the process at the start of supplying the operating power is being executed.

Feature αB4. The game machine according to any one of the features αB1 to αB3, wherein the interrupt process includes a power outage monitoring process (step S8901) for monitoring the occurrence of a power outage.

According to the characteristic αB4, the power outage monitoring process is executed even in the situation where the predetermined setting-related process is executed, so that the time required to complete the predetermined setting-related process may be long. Even in this case, when a power failure occurs in the situation where the predetermined setting-related processing is being executed, it is possible to appropriately deal with the power failure.

Feature αB5. The interrupt processing includes a progress corresponding process (step S8907 to step S8920 in the main CPU 63) executed to control the progress of the game,
When the interrupt processing is interrupted and activated in a situation where the predetermined setting-related processing is being executed, the power failure monitoring processing is executed while the progress handling processing is not executed,
When the interrupt processing is interrupted and activated after the processing at the start of supplying the operating power is finished, both the power failure monitoring processing and the progress handling processing can be executed. Amusement machine.

According to the characteristic αB5, in the configuration in which the occurrence of power failure is regularly monitored in the situation where the predetermined setting-related processing is being executed, the interrupt processing is interrupted and activated in the situation where the predetermined setting-related processing is being executed. Even in this case, it is possible to prevent the progress corresponding process for controlling the progress of the game from being executed.

Feature αB6. The setting related execution means,
When the first setting-related operation (ON operation of the setting key insertion portion 68a and pressing operation of the reset button 68c) is performed when the supply of operating power is started, the use as the predetermined setting-related processing is performed. Means for executing a changeable process in which the target setting value can be changed (a function for executing the setting value updating process in the main CPU 63);
Based on the fact that the second setting-related operation (ON operation of the setting key insertion portion 68a) is performed when the supply of the operating power is started, as the predetermined setting-related processing, the setting value to be used is set. Means for executing setting notification processing for notification (a function for executing setting confirmation processing in the main CPU 63);
Equipped with
The permission setting unit sets a state in which the execution of the interrupt processing is permitted from a state in which the execution of the interrupt processing is prohibited when the changeable processing is executed in the processing when the supply of the operating power is started. When the setting notification process is executed in the process at the time of starting the supply of the operating power, the state in which the execution of the interrupt process is prohibited is set to the state in which the execution of the interrupt process is permitted. The gaming machine according to any one of the features αB1 to αB5.

According to the characteristic αB6, since the first setting-related operation needs to be performed when the supply of the operating power is started in order to change the setting value to be used, the setting value to be used is illegally changed. It becomes possible to make it difficult to perform the intended action. Further, when the supply of operating power is started, the setting value of the usage target is notified by performing the second setting related operation, so that the manager of the game hall confirms the setting value of the usage target as necessary. It becomes possible.

For the configurations of the features αB1 to αB6, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the inventions related to the characteristic z group, the characteristic αA group, and the characteristic αB group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, it is necessary to suitably perform the processing when the supply of the operating power is started, and there is still room for improvement in this respect.

<Characteristic αC group>
Features αC1. Means for executing profit-giving processing in a mode corresponding to a setting value set as a usage target among setting values of a plurality of stages corresponding to the player's advantage (processing of steps S503 and S504 in the main CPU 63) Function to execute)
Setting-related executing means (a function for executing setting value updating processing in the main CPU 63) that executes a predetermined setting-related processing relating to the setting value when supply of operating power is started;
When the supply of the operating power is stopped before the completion of the predetermined setting-related processing and then the supply of the operating power is started, the restriction that the execution of the predetermined progress processing for advancing the game is restricted A regulation means (a function of making a positive judgment in step SB808 in the main CPU 63 in the 53rd embodiment, a function of making a positive judgment in steps SC108 and SC116 in the main CPU 63 in the 54th embodiment). ,
A gaming machine characterized by being equipped with.

According to the characteristic αC1, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player can use the more advantageous setting value as the usage target. Will be expected. In this case, if the supply of the operating power is stopped before the completion of the predetermined setting-related processing, and if the supply of the operating power is resumed after that, the execution of the predetermined progress processing for advancing the game is restricted. It As a result, it is possible to prevent the predetermined progress processing for advancing the game from being executed even though the predetermined setting-related processing is not completed.

Feature αC2. The regulation means executes the predetermined setting-related process even when the supply of the operating power is stopped after the supply of the operating power is stopped before the completion of the predetermined setting-related process. The gaming machine described in the feature αC1 is characterized in that the regulation state is not established in the case of the above.

According to the feature αC2, it is possible to prevent the execution of the predetermined progress processing for advancing the game from being restricted until the predetermined setting-related processing is executed when the supply of the operating power is restarted. ..

Features αC3. A feature αC1 including a means (a function of executing the processing of steps S8901 to S8905 in the main CPU 63) that executes a non-regulation processing different from the predetermined progress processing even in the restriction state The gaming machine described in αC2.

According to the characteristic αC3, the non-restriction process can be executed even in the situation where the execution of the predetermined progress process is restricted. As a result, it becomes possible to ensure the execution of the required processing even in the restricted state.

Features αC4. The gaming machine according to feature αC3, wherein the non-restriction process includes a power failure monitoring process (step S8901) for monitoring the occurrence of a power failure.

According to the feature αC4, the power outage monitoring process is executed even in the regulated state, so that when a power outage occurs in the regulated state, it is possible to appropriately cope with the power outage.

Features αC5. The features αC1 to αC4 are characterized in that the regulation means brings the regulation state into the regulation state when the supply of the operation power is resumed even if the supply of the operation power is stopped in the state of the regulation state. The gaming machine according to any one of 1.

According to the characteristic αC5, it is possible to prevent the state in which the execution of the predetermined progress processing is restricted from being released only by stopping the supply of the operating power.

Features αC6. Means for executing a notification that allows the player to recognize that the predetermined setting-related processing is to be executed based on the fact that the restricted state has been reached (in the 53rd embodiment, Any one of features αC1 to αC5 characterized in that the main CPU 63 has a function of executing the process of step SB825, and in the 54th embodiment, a function of executing the process of step SC127 of the main CPU 63). The game machine described.

According to the characteristic αC6, when the supply of the operating power is stopped before the predetermined setting-related processing is completed, it is possible to prompt the game hall manager to execute the predetermined setting-related processing again. Become.

Features αC7. Even when the supply of the operating power is stopped after the supply of the operating power is stopped before the completion of the predetermined setting-related processing, the restricting unit controls the specific related operation (setting key insertion unit 68a). The game machine according to any one of the features αC1 to αC6, wherein the regulation state is not set based on the ON operation and the pressing operation of the reset button 68c).

According to the characteristic αC7, even if the supply of the operating power is stopped before the completion of the predetermined setting-related processing, the game is advanced by performing the specific related operation when the supply of the operating power is restarted. It is possible to prevent the execution of the predetermined progress processing of 1. from being restricted.

Feature αC8. The gaming machine according to feature αC7, wherein the setting-related executing means executes the predetermined setting-related process based on the fact that the specific-related operation is performed when supply of operating power is started. ..

According to the characteristic αC8, it becomes possible to prevent the execution of the predetermined progress processing for advancing the game from being restricted until the predetermined setting-related processing is executed when the supply of the operating power is restarted. ..

Feature αC9. For the specific related operation, the setting key insertion portion (setting key insertion portion 68a) is set to a predetermined corresponding state (ON operation state) by the setting key, and another predetermined operation (press operation of the reset button 68c). ) Is being done,
When the supply of the operating power is stopped before the supply of the operating power is completed before the completion of the predetermined setting-related processing, and the supply of the operating power is started thereafter, the other predetermined operation is not performed. The gaming machine according to feature αC8, wherein the setting key insertion portion is not brought into the restricted state based on the predetermined corresponding state.

According to the feature αC9, even if the specific related operation is not performed when the supply of the operating power is restarted, the setting key insertion portion is in the predetermined corresponding state, and thus the predetermined progress processing for advancing the game is executed. Can be prevented from being regulated. As a result, when the supply of the operating power is stopped during the execution of the predetermined setting-related processing, the setting key insertion part is in the predetermined corresponding state but the power is turned on without performing another predetermined operation. Even if there is, it is possible to prevent the execution of the predetermined progress processing from being restricted.

Feature αC10. When the supply of operating power is started, the setting key insertion unit is brought into the predetermined corresponding state in a situation where the other predetermined operation is not performed, and another related process regarding the set value is executed. The gaming machine according to feature αC9, which is provided with another related execution means (a function for executing the setting confirmation process in the main CPU 63).

According to the characteristic αC10, even if the supply of the operating power is stopped before the completion of the predetermined setting-related process, the operation for executing another related process when the supply of the operating power is restarted is performed. It is possible to prevent the execution of the predetermined progress processing for advancing the game from being restricted.

Feature αC11. When the supply of the operating power is stopped before the completion of the predetermined setting-related processing and then the supply of the operating power is started, the setting key insertion unit is operated in a situation where the other predetermined operation is not performed. The predetermined setting-related process is executed without executing the another related process based on the fact that is set to the predetermined corresponding state, the gaming machine according to the feature αC10.

According to the characteristic αC11, when the supply of the operating power is stopped before the completion of the predetermined setting related process, the operation for executing another related process when the supply of the operating power is restarted is performed. A predetermined setting related process is executed instead of another related process. This makes it possible to give priority to the execution of the predetermined setting-related processing.

Features αC12. The predetermined setting-related processing is processing that enables changing the setting value to be used,
The gaming machine according to feature αC11, wherein the different related process is a process for notifying the setting value to be used.

According to the characteristic αC12, when the supply of the operating power is stopped while the setting value to be used is being changed, the setting value to be used is notified when the supply of the operating power is resumed thereafter. It is possible to give priority to the execution of the process for changing the setting value to be used rather than the process.

Features αC13. The gaming machine according to any one of features αC1 to αC12, wherein the predetermined setting-related process is a process that enables changing a setting value to be used.

According to the characteristic αC13, when the supply of the operating power is stopped during the process for changing the setting value to be used, the game is advanced when the supply of the operating power is resumed after that. Execution of the predetermined progress processing is restricted. As a result, it is possible to prevent the predetermined progress processing for advancing the game from being executed despite the situation where the change of the set value is not completed.

In addition, with respect to the configurations of the features αC1 to αC13, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, and features βA1 to βA. 4. Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αD group>
Features αD1. Means for executing profit-giving processing in a mode corresponding to a setting value set as a usage target among setting values of a plurality of stages corresponding to the player's advantage (processing of steps S503 and S504 in the main CPU 63) Function to execute)
Predetermined setting-related processing relating to the set value is executed based on the fact that a specific related operation (ON operation of the setting key insertion portion 68a and pressing operation of the reset button 68c) is performed when supply of operating power is started. Setting-related execution means (a function of executing setting value update processing in the main CPU 63),
Based on the fact that a predetermined related operation (ON operation of the setting key insertion unit 68a) is performed when the supply of operating power is started, another related execution means (main Function for executing the setting value update processing in the side CPU 63),
When the supply of the operating power is stopped before the completion of the predetermined setting-related processing and then the supply of the operating power is started, the restriction that the execution of the predetermined progress processing for advancing the game is restricted A regulation means (a function of making a positive judgment in step SB808 in the main CPU 63 in the 53rd embodiment, a function of making a positive judgment in steps SC108 and SC116 in the main CPU 63 in the 54th embodiment). ,
Equipped with
Even if the supply of the operating power is stopped before the predetermined setting-related processing is completed, the regulation means performs the specific related operation when the supply of the operating power is started after that. If the supply of the operating power is started after that even if the supply of the operating power is stopped before the predetermined setting related processing is completed, A gaming machine that is not brought into the restricted state based on a predetermined related operation being performed.

According to the characteristic αD1, the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, so that the player can use the more advantageous setting value as the usage target. Will be expected. In this case, if the supply of the operating power is stopped before the completion of the predetermined setting-related processing, and if the supply of the operating power is resumed after that, the execution of the predetermined progress processing for advancing the game is restricted. It As a result, it is possible to prevent the predetermined progress processing for advancing the game from being executed even though the predetermined setting-related processing is not completed.

Further, even when the supply of the operating power is stopped before the completion of the predetermined setting-related processing, the execution of the predetermined progress processing is not restricted because the specific related operation is performed when the supply of the operating power is restarted. As a result, it is possible to prevent the execution of the predetermined progress processing for advancing the game from being restricted until the predetermined setting-related processing is executed when the supply of the operating power is restarted.

Even if the supply of the operating power is stopped before the completion of the predetermined setting-related processing, the execution of the predetermined progress processing is restricted even when the predetermined related operation is performed when the supply of the operating power is restarted. Not done. This makes it possible to prevent the execution of the predetermined progress processing from being restricted when the operation for executing the processing related to the set value is performed.

Feature αD2. Based on that the predetermined related operation is performed when the supply of the operating power is started after the supply of the operating power is stopped before the completion of the predetermined setting related process, the another related process The gaming machine according to feature αD1, wherein the predetermined setting-related processing is performed without being performed.

According to the characteristic αD2, in the case where the supply of the operating power is stopped before the completion of the predetermined setting related process, the operation for executing another related process when the supply of the operating power is resumed is performed. A predetermined setting related process is executed instead of another related process. This makes it possible to give priority to the execution of the predetermined setting-related processing.

Feature αD3. For the specific related operation, the setting key insertion portion (setting key insertion portion 68a) is set to a predetermined corresponding state (ON operation state) by the setting key, and another predetermined operation (press operation of the reset button 68c). ) Is being done,
The predetermined related operation includes that the setting key insertion portion is brought into the predetermined corresponding state by the setting key, and does not include that the other predetermined operation is performed. Gaming machine described in.

According to the characteristic αD3, even if the specific related operation is not performed when the supply of the operating power is restarted, the setting key insertion portion is in the predetermined corresponding state, so that the predetermined progress processing for advancing the game is executed. Can be prevented from being regulated. As a result, when the supply of the operating power is stopped during the execution of the predetermined setting-related processing, the setting key insertion part is in the predetermined corresponding state but the power is turned on without performing another predetermined operation. Even if there is, it is possible to prevent the execution of the predetermined progress processing from being restricted.

Feature αD4. The predetermined setting-related processing is processing that enables changing the setting value to be used,
The gaming machine according to any one of features αD1 to αD3, wherein the another related process is a process for notifying the setting value to be used.

According to the characteristic αD4, when the supply of the operating power is stopped during the process for changing the setting value to be used, the game is advanced when the supply of the operating power is resumed after that. Execution of the predetermined progress processing is restricted. As a result, it is possible to prevent the predetermined progress processing for advancing the game from being executed despite the situation where the change of the set value is not completed. Also, if the supply of operating power is stopped while changing the setting value to be used, a process that enables changing the setting value to be used when restarting the supply of operating power is performed. The predetermined progress processing is performed not only when the operation for performing the operation is performed but also when the operation for performing the processing for notifying the setting value to be used is performed. It is possible to prevent the execution of the.

Feature αD5. Features αD1 to A1 which are characterized by including a unit (a function of executing the processes of steps S8901 to S8905 in the main CPU 63) that executes a non-regulation process different from the predetermined progress process even in the restriction state. The gaming machine described in any one of αD4.

According to the feature αD5, the non-restriction process can be executed even in the situation where the execution of the predetermined progress process is restricted. As a result, it becomes possible to ensure the execution of the required processing even in the restricted state.

Features αD6. The game machine according to feature αD5, wherein the non-restriction process includes a power failure monitoring process (step S8901) for monitoring occurrence of a power failure.

According to the feature αD6, the power outage monitoring process is executed even in the regulated state, so that when the power outage occurs in the regulated state, it is possible to appropriately cope with the power outage.

Features αD7. The features αD1 to αD6 are characterized in that the regulation means brings the regulation state into the regulation state when the supply of the operation power is resumed even if the supply of the operation power is stopped in the situation of the regulation state. The gaming machine according to any one of 1.

According to the feature αD7, it is possible to prevent the state in which the execution of the predetermined progress processing is restricted from being canceled only by stopping the supply of the operating power.

Feature αD8. Means for executing a notification that allows the player to recognize that the predetermined setting-related processing is to be executed based on the fact that the restricted state has been reached (in the 53rd embodiment, Any one of features αD1 to αD7 characterized in that the main CPU 63 has a function of executing the process of step SB825, and in the 54th embodiment, a function of executing the process of step SC127 of the main CPU 63). The game machine described.

According to the feature αD8, when the supply of operating power is stopped before completing the predetermined setting-related processing, it is possible to prompt the game hall manager to execute the predetermined setting-related processing again. Become.

Feature αD9. Means for executing profit-giving processing in a mode corresponding to a setting value set as a usage target among setting values of a plurality of stages corresponding to the player's advantage (processing of steps S503 and S504 in the main CPU 63) Function to execute)
Predetermined setting-related processing relating to the set value is executed based on the fact that a specific related operation (ON operation of the setting key insertion portion 68a and pressing operation of the reset button 68c) is performed when supply of operating power is started. Setting-related execution means (a function of executing setting value update processing in the main CPU 63),
When the supply of the operating power is stopped before the completion of the predetermined setting-related processing and then the supply of the operating power is started, the restriction that the execution of the predetermined progress processing for advancing the game is restricted A regulation means (a function of making a positive judgment in step SB808 in the main CPU 63 in the 53rd embodiment, a function of making a positive judgment in steps SC108 and SC116 in the main CPU 63 in the 54th embodiment). ,
Equipped with
The specific related operation includes a first related operation (ON operation of the setting key insertion portion 68a) and a second related operation (press operation of the reset button 68c),
Even if the supply of the operating power is stopped before the completion of the predetermined setting-related processing, the regulation means performs the specific related operation when the supply of the operating power is started after that. If the supply of the operating power is started after that even if the supply of the operating power is stopped before the predetermined setting related processing is completed, A gaming machine, wherein the restricted state is not set based on the first related operation being performed among the first related operation and the second related operation.

According to the characteristic αD9, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage degree of the player, the player sets the more advantageous setting value as the usage target. Will be expected. In this case, if the supply of the operating power is stopped before the completion of the predetermined setting-related processing, and if the supply of the operating power is resumed after that, the execution of the predetermined progress processing for advancing the game is restricted. It As a result, it is possible to prevent the predetermined progress processing for advancing the game from being executed even though the predetermined setting-related processing is not completed.

Further, even when the supply of the operating power is stopped before the completion of the predetermined setting-related processing, the execution of the predetermined progress processing is not restricted because the specific related operation is performed when the supply of the operating power is restarted. As a result, it is possible to prevent the execution of the predetermined progress processing for advancing the game from being restricted until the predetermined setting-related processing is executed when the supply of the operating power is restarted.

Even when the supply of the operating power is stopped before the completion of the predetermined setting-related process, the execution of the predetermined progress process is restricted if the first related operation is performed when the supply of the operating power is restarted. Not done. This makes it possible to prevent the execution of the predetermined progress processing from being restricted when a part of the operations for executing the predetermined setting-related processing is performed.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features αD1 to αD9. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αE group>
Feature αE1. Means for executing profit-giving processing in a mode corresponding to a setting value set as a usage target among setting values of a plurality of stages corresponding to the player's advantage (processing of steps S503 and S504 in the main CPU 63) Function to execute)
When the supply of operating power is started, it is possible to change the set value to be used based on the fact that a specific related operation including the operation of the predetermined corresponding operation means is performed (a settable condition (set value). Situation generating means (a function for making an affirmative judgment in step SB812 in the main CPU 63 in the 53rd embodiment, and a step SC113 in the main CPU 63 in the 54th embodiment). Function to make an affirmative decision)
An operation specifying means (a function of executing the processing of step SB910 in the main CPU 63) for specifying whether or not the predetermined corresponding operation means is operated;
When the operation identifying unit identifies that the predetermined corresponding operating unit is not operated, the storage state becomes the non-operation corresponding state, and the operation identifying unit identifies that the predetermined corresponding operating unit is operated. An operation-corresponding storage unit (OFF confirmation flag 361) whose storage state becomes an operation-corresponding state when
Selection is made based on the fact that the operation specifying means specifies that the predetermined correspondence operation means is operated in a situation where the storage state of the operation correspondence storage means is the non-operation correspondence state in the setting possible state. Selection target changing means for changing the target set value (function of executing the process of step SB914 in the main CPU 63),
Equipped with
When the termination trigger occurs in the setting possible situation, the setting value that is the selection target is the setting value that is the usage target,
The gaming machine sets the storage state of the operation correspondence storage means to the operation correspondence state when the setting possible situation is started or when the setting possible situation is started (fifth embodiment). A game machine having a function of executing the process of step SB901 in the main CPU 63, and a function of executing the process of step SC114 in the main CPU 63 in the 54th embodiment.

According to the characteristic αE1, the setting value to be used is set from the setting values of the plurality of stages corresponding to the advantage of the player, so that the player can use the more advantageous setting value as the usage target. Will be expected. Further, in order to generate a settable situation in which the set value to be used can be changed, it is necessary to turn on the power supply in a state where a specific related operation including an operation of the predetermined corresponding operation means is performed. Therefore, it becomes possible to make it difficult to illegally change the setting value to be used. In addition, since the setting value to be selected is changed based on the operation of the predetermined corresponding operating means operated to generate the settable condition, the number of operating means necessary to change the setting value is set. It becomes possible to suppress. Further, in the settable situation, the set value to be selected is changed based on the fact that the predetermined correspondence operation means is specified to be operated in the situation where the storage state of the operation correspondence storage means is the non-operation correspondence state. Therefore, it is possible to prevent the setting value to be selected from being changed a plurality of times for one operation of the predetermined corresponding operation means.

In this case, the storage state of the operation correspondence storage means is set to the operation correspondence state when the settable situation is started or when the settable situation is started. As a result, when the operation of the predetermined corresponding operation means for causing the settable situation continues even after the start of the settable situation, the operation of the predetermined corresponding operation means causes a change in the setting value to be selected. It is possible to prevent it from happening.

Feature αE2. In the situation generating means, when the detection state of the means for detecting the operation of the predetermined correspondence operating means is the operation detection state, the predetermined correspondence operating means is operated regardless of the storage state of the operation correspondence storing means. The gaming machine described in the feature αE1 characterized by being specified.

According to the feature αE2, when specifying whether or not the specific related operation is performed, it is not specified whether or not the predetermined corresponding operation means is switched from the unoperated state to the operated state, but the predetermined corresponding operation is performed. Since it is a configuration that specifies whether or not the means is being operated, it is possible to simplify the processing configuration for specifying whether or not to generate the settable status.

Features αE3. A setting correspondence storage unit (setting reference area 341) for storing setting correspondence information corresponding to the setting value to be used,
A selection correspondence storage unit (setting update area 342) that stores selection correspondence information corresponding to the setting value that is the selection target;
Equipped with
The selection target changing unit specifies that the predetermined corresponding operating unit is operated by the operation specifying unit in a situation where the storage state of the operation corresponding storage unit is the non-operation corresponding state in the setting possible state. On the basis of this, the selection correspondence information stored in the selection correspondence storage means is changed so that the setting value as the selection target is changed,
The situation generation means stores information corresponding to the selection correspondence information stored in the selection correspondence storage means in the setting correspondence storage means as the setting correspondence information when the termination trigger occurs in the setting possible situation. The game machine according to the feature αE1 or αE2, in which the setting value that has been the selection target in the setting possible state is set as the use target.

According to the feature αE3, the setting correspondence storage unit that stores the setting correspondence information corresponding to the setting value to be used and the selection correspondence storage unit that stores the selection correspondence information corresponding to the setting value being changed in the settable state. By being provided, it becomes possible to change the set value in the settable situation while storing and holding the information of the set value set before the start of the settable situation.

Features αE4. Means for causing the display of the set value that is the selection target in the settable status to be performed by a predetermined display means (first to fourth notification display devices 201 to 204) (step SA801 in the main CPU 63) ~ The function of executing the processing of step SA803) is provided, The gaming machine according to any one of the features αE1 to αE3.

According to the feature αE4, it is possible to perform the setting value changing operation while confirming the setting value which is being changed in the setting possible state.

Features αE5. Means for executing profit-giving processing in a mode corresponding to a setting value set as a usage target among setting values of a plurality of stages corresponding to the player's advantage (processing of steps S503 and S504 in the main CPU 63) Function to execute)
When the supply of operating power is started, it is possible to change the set value to be used based on the fact that a specific related operation including the operation of the predetermined corresponding operation means is performed (a settable condition (set value). Situation generating means (a function for making an affirmative judgment in step SB812 in the main CPU 63 in the 53rd embodiment, and a step SC113 in the main CPU 63 in the 54th embodiment). Function to make an affirmative decision)
An operation specifying means (a function of executing the processing of step SB910 in the main CPU 63) for specifying whether or not the predetermined corresponding operation means is operated;
Selection target changing means for changing the setting value to be selected based on the fact that the operation specifying means specifies that the predetermined correspondence operation means is operated in the setting possible state (step SB914 in the main CPU 63). Function that executes the process of
Equipped with
When the termination trigger occurs in the setting possible situation, the setting value that is the selection target is the setting value that is the usage target,
In the gaming machine, the operation of the predetermined corresponding operation means when the supply of the operating power for generating the settable situation is started triggers the change of the set value to be selected in the settable situation. Means to prevent it from being treated as an operation (a function to execute the process of step SB901 in the main CPU 63 in the 53rd embodiment, a function to execute the process of step SC114 in the main CPU 63 in the 54th embodiment) are provided. A gaming machine characterized by being.

According to the characteristic αE5, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the degree of advantage of the player, the player is allowed to use the more advantageous setting value. Will be expected. Further, in order to generate a settable situation in which the set value to be used can be changed, it is necessary to turn on the power supply in a state where a specific related operation including an operation of the predetermined corresponding operation means is performed. Therefore, it becomes possible to make it difficult to illegally change the setting value to be used. In addition, since the setting value to be selected is changed based on the operation of the predetermined corresponding operating means operated to generate the settable condition, the number of operating means necessary to change the setting value is set. It becomes possible to suppress.

In this case, the operation of the predetermined corresponding operation means when the supply of the operating power for generating the settable status is started is treated as the operation that triggers the change of the setting value to be selected in the settable status. Not to be. As a result, when the operation of the predetermined corresponding operation means for causing the settable situation continues even after the start of the settable situation, the operation of the predetermined corresponding operation means causes a change in the setting value to be selected. It is possible to prevent it from happening.

In addition, with respect to the configurations of the features αE1 to αE5, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the inventions related to the characteristic αC group, the characteristic αD group, and the characteristic αE group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as exemplified above, it is necessary to make the configuration relating to the set value that determines the advantage of the gaming machine suitable, and there is still room for improvement in this respect.

<Characteristic αF group>
Features αF1. Specific display means (special figure display section 37a, general figure display section 38a),
Display data setting means (function of executing the process of step S8915 in the main CPU 63) for setting display data in the display storage area (first display data buffer 271, third display data buffer 273);
A specific display control means (a function of executing the processing of steps SC412 to SC414 in the main CPU 63) for controlling the display of the specific display means so that a display corresponding to the display data stored in the display storage area is performed; ,
Initializing means for initializing a predetermined storage area (clearing target area 371 in the 55th embodiment) based on the start of supply of operating power (second RAM clear of main CPU 63 in the 55th embodiment) Function to execute processing),
Equipped with
A game machine characterized in that the display storage area is not initialized by the initialization means.

According to the feature αF1, it is possible to start the game in a situation where the predetermined storage area is initialized by initializing the predetermined storage area based on the start of the supply of the operating power. It will be possible. In this case, even if the predetermined storage area is initialized, the display storage area in which the display data for causing the specific display means to display is set is not initialized by the initialization means. With this, the display content of the specific display means when the supply of the operating power is started, whether the predetermined storage area is initialized by the initializing means or not, is the operating power. It is possible to display the contents before the supply of the. Therefore, even if the player confirms the display content of the specific display means when the supply of the operating power is started, it cannot be specified whether or not the predetermined storage area has been initialized by the initialization means. It becomes possible.

Features αF2. Setting means for setting a setting value to be used from setting values of a plurality of stages corresponding to the advantage of the player in a setting possible situation generated based on the start of supply of operating power (55th). The function of executing the processing of step SC216 of the main CPU 63 in the embodiment),
The initialization means initializes the predetermined storage area when the setting value to be used is set by the setting means or after the setting value to be used is set by the setting means. The gaming machine described in the feature αF1.

According to the characteristic αF2, a predetermined storage area is initialized by the initialization means when a new setting of the setting value to be used is performed when the supply of the operating power is started, or when the setting value is newly set. As a result, when a new setting value to be used is set, it is possible to start the game in a situation where a predetermined storage area is initialized. In this case, even if a predetermined storage area is initialized by the initialization means in association with the new setting of the setting value to be used, the display data for causing the specific display means to display is set. The display storage area is not initialized by the initialization means. As a result, the display content of the specific display means when the supply of the operating power is started is changed when the setting value to be used is newly set and the setting value to be used is newly set. In either case, the display content before the supply of the operating power is stopped can be performed. Therefore, even if the player confirms the display content of the specific display means when the supply of the operating power is started, it is not possible to specify whether or not a new setting of the setting value to be used is performed. Is possible.

Features αF3. When the predetermined initialization condition is satisfied when the supply of the operating power is started (the information abnormality regarding the main RAM 65 does not occur, and the setting update display flag and the game stop flag are not set to "1"). In the case where a “RAM clear operation” is performed in a situation), another initialization unit that initializes the predetermined storage area even when the setting value to be used is not set by the setting unit ( A function of executing the first RAM clearing process of the main CPU 63 in the 55th embodiment),
The gaming machine according to feature αF2, wherein the display storage area is not initialized by the different initialization means.

According to the characteristic αF3, even when the setting value to be used is not newly set when the predetermined initialization condition is satisfied when the supply of the operating power is started, the predetermined storage area is set. Is initialized, it is possible to start the game in a situation where a predetermined storage area is initialized even in a situation where a new setting value to be used is not set. In this case, the display data for causing the specific display means to display is set regardless of whether the setting value to be used is newly set or the predetermined initialization condition is satisfied. The display storage area is not initialized. With this, the display content of the specific display means when the supply of the operating power is started is initialized to a predetermined value when a new setting value is set, when a new setting value is not set. Regardless of whether the condition is satisfied or the predetermined initialization condition is not satisfied, the display content before the supply of the operating power is stopped can be performed. Therefore, even if the player confirms the display content of the specific display means when the supply of the operating power is started, whether a new setting value is set and whether a predetermined initialization condition is satisfied. It becomes possible not to specify.

Features αF4. It is characterized in that it is provided with means (power supply/firing control device 78) for supplying backup power to the display storage area and the predetermined storage area in a situation where operating power is not supplied to the specific display control means. The gaming machine according to any one of the features αF1 to αF3.

According to the characteristic αF4, even if the display storage area and the predetermined storage area have a configuration in which the operating power needs to be supplied for storing and holding information, in the situation where the specific display control means is not supplied with the operating power. Since backup power is supplied to the display storage area and the predetermined storage area, information should be stored and retained in the display storage area and the predetermined storage area even when operating power is not supplied to the specific display means. Is possible.

Features αF5. It is determined whether or not to give a privilege to the player, and when the privilege is given to the player, the privilege giving information (information of "1" set in the flag corresponding to the kind of the jackpot result) is given as above. An assignment determination means (a function of executing the process of step S508 in the main CPU 63) to be stored in the storage area;
A privilege granting unit for granting a privilege (opening/closing execution mode) to a player based on the privilege granting information stored in the predetermined storage area (a function of executing the processes of steps S408 to S412 in the main CPU 63). )When,
Equipped with
The display data setting means stores the display data (display data selected in step S507 or step S509) corresponding to the result determined by the grant determining means when the display timing of the determination result comes, in the display storage area. Set to
The specific display control means controls the display of the specific display means so that the display corresponding to the result-corresponding display data stored in the display storage area is performed, thereby responding to the determination result of the assignment determination means. The gaming machine according to any one of the features αF1 to αF4, characterized in that the display is performed by the specific display means.

According to the characteristic αF5, the player pays attention to the specific display means by performing the display corresponding to the determination result of whether or not to give the privilege to the player on the specific display means. In this case, since the configuration described in the above characteristic αF1 is provided, even if the predetermined storage area is initialized by the initialization means when the supply of the operating power is started, the display is performed on the specific display means. The display storage area in which the display data for displaying is set is not initialized by the initialization means. With this, the display content of the specific display means when the supply of the operating power is started, whether the predetermined storage area is initialized by the initializing means or not, is the operating power. It is possible to display the contents before the supply of the. Therefore, even if the player confirms the display content of the specific display means when the supply of the operating power is started, it cannot be specified whether or not the predetermined storage area has been initialized by the initialization means. It becomes possible.

Features αF6. Even when the privilege giving information is erased from the predetermined storage area by the initialization means initializing the predetermined storage area, the display storage area is not initialized by the initialization means. The gaming machine according to feature αF5.

According to the characteristic αF6, when the predetermined storage area is initialized when the supply of the operation power is started, the privilege giving information is erased from the predetermined storage area, so that the supply of the operation power is stopped. Even if the privilege giving information is stored in a predetermined storage area before the game is started, it is possible to start the game in a state where the privilege giving information is erased when the supply of the operating power is restarted. In this case, even when the privilege granting information is deleted from the predetermined storage area in this way, the display storage area in which the display data for causing the specific display means to display is set is initialized by the initialization means. Not be converted. Thereby, even if the player confirms the display content of the specific display means when the supply of the operating power is started, it is not possible to specify whether or not the predetermined storage area is initialized by the initialization means. It becomes possible to prioritize things.

Features αF7. As the specific display means, a first specific display means (special figure display section 37a) and a second specific display means (general figure display section 38a) are provided,
As the display storage area, a first display storage area (first display data buffer 271) and a second display storage area (third display data buffer 273) are provided,
The display data setting means,
First display data setting means for setting display data in the first display storage area (function of executing the process of step S8915 in the main CPU 63 with respect to the special figure display portion 37a);
Second display data setting means for setting display data in the second display storage area (a function of executing the process of step S8915 in the main CPU 63 with respect to the general figure display portion 38a);
Equipped with
The specific display control means,
First specific display control means for controlling the display of the first specific display means such that a display corresponding to the display data stored in the first display storage area is performed (step in the main CPU 63 regarding the special figure display portion 37a). SC412 to the function of executing the processing of step SC414),
Second specific display control means for controlling the display of the second specific display means so that a display corresponding to the display data stored in the second display storage area is performed (steps in the main CPU 63 regarding the general figure display portion 38a). SC412 to the function of executing the processing of step SC414),
Equipped with
The gaming machine according to any one of features αF1 to αF6, wherein the first display storage area and the second display storage area are not initialized by the initialization unit.

According to the characteristic αF7, the display contents when the supply of the operating power is started for both the first specific display means and the second specific display means are displayed when the predetermined storage area is initialized by the initialization means, and It is possible to set the display content before the supply of the operating power is stopped in any case where the initialization is not performed. Therefore, even if the player confirms the display content of either the first specific display means or the second specific display means when the supply of the operating power is started, the initialization means initializes the predetermined storage area. It becomes possible not to specify whether or not it was broken.

Features αF8. The processing for starting the supply of the operating power is executed when the supply of the operating power is started, and the processing for initializing the predetermined storage area by the initialization unit is performed when the supply of the operating power is started. The configuration included in the processing of
Any of the characteristics αF1 to αF7, wherein the specific display control means starts the display of the specific display means after the processing at the start of the supply of the operating power is completed when the supply of the operating power is started. The gaming machine described in 1.

According to the feature αF8, whether the predetermined storage area is initialized by the initialization means or not, the specific display means is provided at a timing after the processing at the start of supplying the operating power is completed. It is possible to start the display at.

Features αF9. Based on the start of the supply of operating power, a setting possible state in which a setting value to be used can be set from a plurality of setting values corresponding to the advantage of the player is set. Situation generating means (function of executing the process of step SC216 of the main CPU 63 in the 55th embodiment),
The initialization means is configured to initialize the predetermined storage area when the setting possible situation occurs or after the setting possible situation occurs,
The gaming machine according to feature αF8, wherein the settable situation occurs in a situation where a process at the start of supplying the operating power is being executed.

According to the characteristic αF9, the display on the specific display means is started at the timing after the processing at the start of the supply of the operating power is finished, regardless of whether the setting possible situation occurs or not. It becomes possible to do.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features αF1 to αF9. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αG group>
Features αG1. Specific display means (special figure display section 37a, general figure display section 38a),
Display data setting means (function of executing the process of step S8915 in the main CPU 63) for setting display data in the display storage area (first display data buffer 271, third display data buffer 273);
A specific display control means (a function of executing the processing of steps SC412 to SC414 in the main CPU 63) for controlling the display of the specific display means so that a display corresponding to the display data stored in the display storage area is performed; ,
An initialization unit (mainly in the 56th embodiment) for initializing a predetermined storage area including the display storage area (clear target area 371 in the 56th embodiment) based on the start of supply of operating power. Function of executing the second RAM clearing process of the side CPU 63),
Equipped with
The display data setting means is configured such that when the predetermined storage area is initialized by the initialization means when the supply of the operating power is started and when the supply of the operating power is started by the initialization means. Correspondence setting means for setting the specific correspondence display data for causing the specific display means to perform the specific correspondence display in the display storage area in any case where the predetermined storage area is not initialized (step SC502 in the main CPU 63). , A function of executing the processing of step SC503, step SC507 and step SC510).

According to the characteristic αG1, it is possible to start the game in a situation where the predetermined storage area is initialized by initializing the predetermined storage area based on the start of the supply of the operating power. It will be possible. In this case, the specific display means performs the specific correspondence display both when the supply of the operating power is started and when the predetermined storage area is initialized and when it is not initialized. With this, even if the player confirms the display content of the specific display means when the supply of the operating power is started, it is impossible to specify whether or not the predetermined storage area is initialized by the initialization means. It becomes possible to do.

Features αG2. Setting means for setting a setting value to be used from setting values of a plurality of stages corresponding to the player's advantage in a setting possible situation generated based on the start of supply of operating power (56th The function of executing the processing of step SC216 of the main CPU 63 in the embodiment),
The initialization means initializes the predetermined storage area when the setting value of the usage target is set by the setting means or after the setting value of the usage target is set by the setting means. The gaming machine according to feature αG1.

According to the characteristic αG2, when the setting value of the use target is set when the supply of the operating power is started, or when the predetermined value is accompanyingly initialized when the set value of the use target is set, the use target is set. When a new setting of the set value is performed, it becomes possible to start the game in a situation where a predetermined storage area is initialized. In this case, the specific display means performs the specific correspondence display both when the predetermined storage area is initialized and when it is not initialized accompanying the new setting of the setting value to be used. With this, even if the player confirms the display content of the specific display means when the supply of the operating power is started, it is not possible to specify whether or not a new setting of the setting value to be used is performed. Is possible.

Features αG3. When the predetermined initialization condition is satisfied when the supply of the operating power is started (the information abnormality regarding the main RAM 65 does not occur, and the setting update display flag and the game stop flag are not set to "1"). In the case where a “RAM clear operation” is performed in a situation), another initialization unit that initializes the predetermined storage area even when the setting value to be used is not set by the setting unit ( A function of executing the first RAM clearing process of the main CPU 63 in the 56th embodiment),
The correspondence setting means sets the specific correspondence display data in the display storage area even when the predetermined storage area is initialized by the separate initialization means when the supply of operating power is started. The gaming machine described in Characteristic αG2.

According to the characteristic αG3, the predetermined storage area is initialized even when the setting value is not set when the predetermined initialization condition is satisfied when the supply of the operating power is started. Even if the setting value is not newly set, it is possible to start the game with the predetermined storage area initialized. In this case, when a new setting value is set, when a new setting value is not set, when a predetermined initialization condition is satisfied, and when a predetermined initialization condition is not satisfied. In either case, the specific display is performed by the specific display means. Thereby, even if the player confirms the display content of the specific display means when the supply of the operating power is started, whether or not a new setting of the set value is performed and whether a predetermined initialization condition is satisfied. It becomes possible not to specify whether or not.

Features αG4. The correspondence setting means is capable of supplying operating power in a predetermined regulation situation (during game times, opening/closing execution mode, variable display times on the universal display section 38a, and normal power open state). If the predetermined storage area is not initialized by the initialization means when the supply of the operating power is started after the stop, the specific correspondence display data is not set in the display storage area. The gaming machine according to any one of the features αG1 to αG3.

According to the characteristic αG4, when the supply of the operating power is stopped in the predetermined regulation situation and the supply of the operating power is started after that, the display storage area is not initialized. Since the specific correspondence display data is not set in, the display data when the supply of the operating power is stopped is stored and held in the display storage area as it is. With this, when the supply of the operating power is stopped in the predetermined regulation situation, and when the supply of the operating power is subsequently started and the predetermined storage area is not initialized, the supply of the operating power is stopped. The display of the specific display means can be started from the display content of the specific display means when the display is stopped.

Features αG5. It is determined whether or not to give a privilege to the player, and when the privilege is given to the player, the privilege giving information (information of "1" set in the flag corresponding to the kind of the jackpot result) is given as above. An assignment determination means (a function of executing the process of step S508 in the main CPU 63) to be stored in the storage area;
A privilege granting unit for granting a privilege (opening/closing execution mode) to a player based on the privilege granting information stored in the predetermined storage area (a function of executing the processes of steps S408 to S412 in the main CPU 63). )When,
Equipped with
The display data setting means stores the display data (display data selected in step S507 or step S509) corresponding to the result determined by the grant determining means when the display timing of the determination result comes, in the display storage area. Set to
The specific display control means controls the display of the specific display means so that the display corresponding to the result-corresponding display data stored in the display storage area is performed, thereby responding to the determination result of the assignment determination means. The gaming machine according to any one of the features αG1 to αG4, characterized in that the display is performed by the specific display means.

According to the characteristic αG5, the player pays attention to the specific display means by performing the display corresponding to the determination result of whether or not to give the privilege to the player on the specific display means. In this case, since the configuration described in the above characteristic αG1 is provided, both when the predetermined storage area is initialized and when it is not initialized when the supply of the operating power is started. The specific display is performed by the specific display means. With this, even if the player confirms the display content of the specific display means when the supply of the operating power is started, it is impossible to specify whether or not the predetermined storage area is initialized by the initialization means. It becomes possible to do.

Features αG6. The specific display control means controls the display of the specific display means such that a display corresponding to the determination result of the assignment determination means is performed after the variable display of the pattern is started,
The correspondence setting means is initialized when the supply of the operating power is stopped in a situation where the variable display of the pattern is being performed by the specific display means, and then the supply of the operating power is started. The gaming machine according to feature αG5, wherein the specific correspondence display data is not set in the display storage area when the predetermined storage area is not initialized by the means.

According to the characteristic αG6, when the supply of the operating power is stopped in the situation where the variable display of the pattern is being performed by the specific display means and the supply of the operating power is started after that, the predetermined storage area is obtained. Since the specific correspondence display data is not set in the display storage area when is not initialized, the display data when the supply of the operating power is stopped is stored and held as it is in the display storage area. As a result, the predetermined storage area is initialized when the supply of the operating power is stopped in the situation where the variable display of the pattern is being performed by the specific display means and the supply of the operating power is started thereafter. If not, it is possible to restart the variable display of the pattern on the specific display means.

Features αG7. When the privilege grant information is stored in the predetermined storage area, the privilege granting unit grants the privilege after the display corresponding to the privilege granting is displayed on the specific display unit. Is something
The correspondence setting unit is configured to perform the initialization by the initialization unit when the supply of the operating power is stopped in a situation where the privilege is provided by the privilege providing unit and the supply of the operating power is subsequently started. The gaming machine according to feature αG5 or αG6, wherein the specific correspondence display data is not set in the display storage region if a predetermined storage region is not initialized.

According to the characteristic αG7, when the supply of the operating power is stopped in the situation where the privilege is granted and the supply of the operating power is started after that, the predetermined storage area is not initialized. Since the specific correspondence display data is not set in the display storage area, the display data when the supply of the operating power is stopped is stored and held as it is in the display storage area. As a result, when the supply of the operating power is stopped in the situation where the privilege is granted, and when the supply of the operating power is started after that, the predetermined storage area is not initialized, It becomes possible to start the display of the specific display means from the display content corresponding to the situation in which is added.

Features αG8. The specific display control means, when the specific display is performed by the specific display means when the supply of the operating power is started, the specific display is performed after the specific display data is set in the display storage area. The gaming machine according to any one of features αG1 to αG7, characterized in that display of means is started.

According to the feature αG8, the display content when the supply of the operating power is stopped before the specific correspondence display is performed when the supply of the operating power is started is prevented from being performed by the specific display means. It becomes possible.

Features αG9. The processing for starting the supply of the operating power is executed when the supply of the operating power is started, and the processing for initializing the predetermined storage area by the initialization unit is performed when the supply of the operating power is started. The configuration included in the processing of
The characteristic display control means starts the display of the specific display means after the processing at the time of starting the supply of the operating power is executed when the supply of the operating power is started. Amusement machine.

According to the characteristic αG9, whether the predetermined storage area is initialized by the initialization means or not, the specific display means is performed at a timing after the process at the start of supplying the operating power is completed. It is possible to start the display at.

Features αG10. Setting means for setting a setting value to be used from setting values of a plurality of stages corresponding to the player's advantage in a setting possible situation generated based on the start of supply of operating power (56th The function of executing the processing of step SC216 of the main CPU 63 in the embodiment),
A configuration in which the initialization unit initializes the predetermined storage area when the setting value of the usage target is set by the setting unit or after the setting value of the usage target is set by the setting unit And
The gaming machine according to feature αG9, wherein the setting of the setting value of the use target by the setting unit occurs in a situation where the process at the start of supplying the operating power is being executed.

According to the characteristic αG10, in the case where the setting value to be used is newly set or not, in the specific display means at the timing after the process at the start of supplying the operating power is completed. It is possible to start the display.

In addition, with respect to the configurations of the features αG1 to αG10, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, and features βA1 to βA. 4. Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αH group>
Features αH1. Specific display means (special figure display section 37a, general figure display section 38a),
Display data setting means for setting display data in the display storage area (first display data buffer 271, third display data buffer 273) (in the 55th to 57th embodiments, main CPU 63 executes the process of step S8915). Function for executing the process of step SC717 in the main CPU 63 in the 58th to 60th embodiments).
A specific display control means (a function of executing the processing of steps SC412 to SC414 in the main CPU 63) for controlling the display of the specific display means so that a display corresponding to the display data stored in the display storage area is performed; ,
Setting means (55th to 55th) for setting a setting value to be used from a plurality of setting values corresponding to the advantage of the player in a setting possible situation that occurs when the supply of operating power is started. A function of executing the processing of step SC216 of the main CPU 63 in the 60th embodiment),
Equipped with
The display content of the specific display means when the supply of the operation power is started is that the setting value to be used is set by the setting means when the supply of the operation power is started, and the operation power When the supply of the game is started, the display contents are such that it is impossible to distinguish that the predetermined value in which the setting value to be used has not been set by the setting means.

According to the characteristic αH1, the setting value to be used is set in the settable situation generated based on the start of the supply of the operating power, so that the setting value to be used is set. Requires that the supply of operating power be newly started, and even if the setting value to be used is illegally set, it becomes difficult to do so. In this case, the display content of the specific display means when the supply of the operating power is started indicates that the set value to be used is set when the supply of the operating power is started, and the supply of the operating power is performed. When is started, the display content is such that it is impossible to distinguish that it is a predetermined situation in which the setting value to be used is not set. Thereby, even if the player confirms the display content of the specific display means when the supply of the operating power is started, it is possible to prevent the player from specifying whether or not the setting value to be used has been set. It will be possible.

Features αH2. Specific display means (special figure display section 37a, general figure display section 38a),
Display data setting means for setting display data in the display storage area (first display data buffer 271, third display data buffer 273) (in the 56th to 57th embodiments, main CPU 63 executes step S8915). Function to execute the process of step SC717 in the main CPU 63 in the 58th to 60th embodiments).
A specific display control means (a function of executing the processing of steps SC412 to SC414 in the main CPU 63) for controlling the display of the specific display means so that a display corresponding to the display data stored in the display storage area is performed; ,
Setting means (56th to 56th) for setting a setting value to be used from among a plurality of setting values corresponding to the player's advantage in a settable situation that occurs when the supply of operating power is started. A function of executing the processing of step SC216 of the main CPU 63 in the 60th embodiment),
Equipped with
The display data setting means is configured by the setting means when the setting value to be used is set by the setting means when the supply of the operating power is started and when the supply of the operating power is started. Correspondence setting means for setting the specific correspondence display data for causing the specific display means to perform the specific correspondence display in the display storage area in any of the predetermined situations in which the setting value to be used is not set. (A function for executing the processing of step SC502, step SC503, step SC507 and step SC510 in the main CPU 63 in the 56th embodiment, and a function for executing the processing of step SC602 and step SC603 in the main CPU 63 in the 57th embodiment. , A function of executing the processing of steps SC802 to SC805 in the main CPU 63 in the 58th embodiment, a function of executing the processing of steps SC902 to SC905 in the main CPU 63 in the 59th embodiment, the 60th embodiment Then, a game machine having a function of executing the processes of steps SD102 to SD105, step SD109, step SD110, step SD113, and step SD114 in the main CPU 63).

According to the characteristic αH2, the setting value to be used is set in the settable situation generated based on the start of the supply of the operating power, so that the setting value to be used is set. Requires that the supply of operating power be newly started, and even if the setting value to be used is illegally set, it becomes difficult to do so. In this case, the setting value to be used is not set when the setting value to be used is set when the supply of the operating power is started and the setting value to be used is not set when the supply of the operating power is started. In any of the predetermined situations, the specific display is displayed by the specific display means. Thereby, even if the player confirms the display content of the specific display means when the supply of the operating power is started, it is possible to prevent the player from specifying whether or not the setting value to be used has been set. It will be possible.

Features αH3. When a predetermined initialization condition is satisfied when supply of operating power is started (information abnormality regarding the main RAM 65 does not occur, and "1" is not set in the setting update display flag and the game stop flag. When a "RAM clear operation" is performed in a situation), another initialization means for initializing the predetermined storage area (function of executing the first RAM clear processing of the main CPU 63 in the 56th to 60th embodiments). Equipped with
The correspondence setting means uses the setting means when the predetermined storage area is initialized by the separate initialization means when the supply of the operating power is started and when the supply of the operating power is started. The gaming machine according to feature αH2, wherein the specific correspondence display data is set in the display storage area in any case where the target setting value is set.

According to the characteristic αH3, when the predetermined initialization condition is satisfied when the supply of the operating power is started, the predetermined storage area is initialized, so the game is performed in the situation where the predetermined storage area is initialized. Can be started. In this case, both when the setting value to be used is set and when the predetermined storage area is initialized, the specific display is displayed by the specific display means when the supply of the operating power is started. Is done. As a result, even if the player confirms the display content of the specific display means when the supply of the operating power is started, either the new setting of the set value to be used or the initialization of the predetermined storage area is performed. It becomes possible to make it impossible to distinguish whether it was broken.

Features αH4. Initializing means for initializing the predetermined storage area when the setting value of the use target is set by the setting means or after the setting value of the use target is set by the setting means (56th- The game machine according to feature αH2 or αH3, which is provided with a function of executing the second RAM clearing process of the main CPU 63 in the sixtyth embodiment.

According to the characteristic αH4, when the setting value of the use target is set when the supply of the operating power is started, or when the predetermined value is accompanyingly initialized when the set value of the use target is set, the use target is set. When a new setting of the set value is performed, it becomes possible to start the game in a situation where a predetermined storage area is initialized. In this case, the setting value to be used is not set when the setting value to be used is set when the supply of the operating power is started and the setting value to be used is not set when the supply of the operating power is started. In any of the predetermined situations, the specific display is displayed by the specific display means. Thereby, even if the player confirms the display content of the specific display means when the supply of the operating power is started, it is possible to prevent the player from specifying whether or not the setting value to be used has been set. It will be possible.

Features αH5. It is determined whether or not to give a privilege to the player, and when the privilege is given to the player, the privilege giving information (information of "1" set in the flag corresponding to the kind of the jackpot result) is given as above. An assignment determination means (a function of executing the process of step S508 in the main CPU 63) to be stored in the storage area;
A privilege granting unit for granting a privilege (opening/closing execution mode) to a player based on the privilege granting information stored in the predetermined storage area (a function of executing the processes of steps S408 to S412 in the main CPU 63). )When,
Equipped with
The display data setting means stores the display data (display data selected in step S507 or step S509) corresponding to the result determined by the grant determining means when the display timing of the determination result comes, in the display storage area. Set to
The specific display control means controls the display of the specific display means so that the display corresponding to the result-corresponding display data stored in the display storage area is performed, thereby responding to the determination result of the assignment determination means. The gaming machine according to any one of features αH2 to αH4, characterized in that the display is performed by the specific display means.

According to the characteristic αH5, the player pays attention to the specific display means by performing the display corresponding to the determination result of whether or not to give the privilege to the player on the specific display means. In this case, since the configuration described in the above characteristic αH1 is provided, when the setting value to be used is set when the supply of the operating power is started, and the supply of the operating power is started. In any of the predetermined situations where the setting value to be used is not set, the specific display is displayed by the specific display means. Thereby, even if the player confirms the display content of the specific display means when the supply of the operating power is started, it is possible to prevent the player from specifying whether or not the setting value to be used has been set. It will be possible.

Features αH6. The gaming machine according to feature αH5, wherein the specific correspondence display data is display data used as display data corresponding to the result.

According to the characteristic αH6, the specific correspondence display is performed by the specific display means when the supply of the operating power is started by using the display data corresponding to the result used for notifying the determination result of the grant determination means. .. As a result, while suppressing the increase in the capacity of the display data, the setting value to be used is set even if the player confirms the display content of the specific display means when the supply of the operating power is started. It becomes possible not to specify whether or not it has occurred.

Features αH7. Among the display data corresponding to the result, the specific correspondence display data is display data used when the grant determining means determines not to grant the privilege to the player. The game machine described.

When the game hall is closed, it is usual that the power supply of the gaming machine is shut off in a situation where the display content corresponding to the decision not to give the privilege to the player has been displayed by the specific display means by the grant determination means. .. In this case, according to the feature αH7, the setting value to be used is set when the setting value to be used is set when the supply of the operating power is started and the setting value to be used when the supply of the operating power is started. In any of the predetermined situations where the setting is not performed, the display content of the specific display means is the display content corresponding to the determination of not granting the privilege to the player by the grant determination means. Thereby, even if the player confirms the display content of the specific display means when the supply of the operation power is started, the display content is the display content that was displayed before the supply of the operation power was stopped. With this, it becomes possible for the player to recognize, and it is possible to make it impossible to specify whether or not the setting value to be used has been set.

Features αH8. There are multiple types of the specific correspondence display data,
The correspondence setting means sets, in the display storage area, the specific correspondence display data to be used from a plurality of types of specific correspondence display data. Game machine.

According to the characteristic αH8, it is possible to diversify the display content of the specific correspondence display of the specific display means when the supply of the operating power is started.

Features αH9. The specific display control means, when the specific display is performed by the specific display means when the supply of the operating power is started, the specific display is performed after the specific display data is set in the display storage area. The gaming machine according to any one of features αH2 to αH8, characterized in that display of means is started.

According to the characteristic αH9, the display content when the supply of the operating power is stopped before the specific correspondence display is performed when the supply of the operating power is started is prevented from being performed by the specific display means. It becomes possible.

Features αH10. The setting means sets the setting value to be used in a situation where processing at the start of supply of operating power is being executed,
The characteristic display control unit starts the display of the specific display unit after the process at the time of starting the supply of the operating power is executed when the supply of the operating power is started. Amusement machine.

According to the characteristic αH10, the process at the start of the supply of the operating power is performed regardless of whether the setting value to be used is set or the setting value to be used is not set. It is possible to start the specific correspondence display on the specific display means at a timing after the end.

Features αH11. When a predetermined initialization condition is satisfied when supply of operating power is started (information abnormality regarding the main RAM 65 does not occur, and "1" is not set in the setting update display flag and the game stop flag. In the case where a "RAM clear operation" is performed), another initialization unit (56th to 56th units) that initializes the predetermined storage area even when the setting value is not set by the setting unit. 60, a function of executing the first RAM clearing process of the main CPU 63 in the embodiment of the present invention,
The separate initialization means initializes the predetermined storage area in a situation where the process at the start of supplying the operating power is being executed,
The correspondence setting means sets the setting by the setting means when the predetermined storage area is initialized by the separate initialization means when the supply of the operating power is started and when the supply of the operating power is started. In any case where a value is set, the specific correspondence display data is set in the display storage area,
In the characteristic αH9 or αH10, the specific display control means starts the display of the specific display means after the process at the start of the supply of the operating power is executed when the supply of the operating power is started. The game machine described.

According to the characteristic αH11, when the predetermined initialization condition is satisfied when the supply of the operating power is started, the predetermined storage area is initialized, so that the setting value of the use target is newly set. Even if there is no situation, it is possible to start the game in a situation where a predetermined storage area is initialized. In this case, both when the setting value to be used is set and when the predetermined storage area is initialized, the specific display is displayed by the specific display means when the supply of the operating power is started. Is done. As a result, even if the player confirms the display content of the specific display means when the supply of the operating power is started, either the new setting of the set value to be used or the initialization of the predetermined storage area is performed. It becomes possible to make it impossible to distinguish whether it was broken. Further, regardless of whether the setting value to be used is set or the predetermined storage area is initialized, the specific display means is provided at a timing after the process at the start of supplying the operating power is completed. It is possible to start the specific correspondence display in.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features αH1 to αH11. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, and features βA1 to βA. 4. Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αI group>
Features αI1. Specific display means (special figure display section 37a, general figure display section 38a),
It is determined whether or not to give a bonus to the player, and when the bonus is given to the player, the bonus giving information (the information of "1" set in the flag corresponding to the kind of the jackpot result) is stored in a predetermined memory. An assignment determining unit (a function of the main CPU 63 that executes the process of step S508) to be stored in the area (the clear target area 371 in the 57th to 60th embodiments);
A privilege granting unit for granting a privilege (opening/closing execution mode) to a player based on the privilege granting information stored in the predetermined storage area (a function of executing the processes of steps S408 to S412 in the main CPU 63). )When,
When the display timing of the determination result is reached, the display data corresponding to the determination result of the assignment determination means (display data selected in step S507 or step S509) is stored in the display storage area (first display data buffer 271, The display data setting means set in the third display data buffer 273 (a function for executing the process of step S8915 in the main CPU 63 in the 57th embodiment, and the main CPU 63 in the 58th to 60th embodiments). Function for executing the processing of step SC717 in step 1),
By controlling the display of the specific display means so that the display corresponding to the result-corresponding display data stored in the display storage area is performed, the display corresponding to the determination result of the grant determination means is the specific display means. Specific display control means (a function of executing the processing of steps SC412 to SC414 in the main CPU 63),
Initialization means (57th to 57th) for initializing a predetermined storage area (clearing target area 371 in the 57th to 60th embodiments) including the display storage area based on the start of supply of operating power. 60) the function of executing the second RAM clearing process of the main CPU 63 in the embodiment,
Equipped with
The display data setting means stores the specific correspondence display data used as the display data corresponding to the result when the predetermined storage area is initialized by the initialization means when the supply of the operating power is started. Corresponding setting means for setting in the display storage area (in the 57th embodiment, the function of executing the processing of step SC602 and step SC603 in the main CPU 63, in the 58th embodiment, the processing of step SC802 to step SC805 in the main CPU 63 Function to be executed, function to execute step SC902 to step SC905 in the main CPU 63 in the 59th embodiment, step SD102 to step SD105, step SD109, step SD110, step SD113 in the main CPU 63 in the 60th embodiment. And a function of executing the processing of step SD114).

According to the feature αI1, the player pays attention to the specific display means by performing the display corresponding to the determination result of whether or not to give the privilege to the player on the specific display means. Further, it is possible to start the game in a situation where the predetermined storage area is initialized by initializing the predetermined storage area based on the start of the supply of the operating power. In this case, when the predetermined storage area is initialized when the supply of the operating power is started, the display data corresponding to the result used for notifying the determination result of the assignment determination means is set in the display storage area. To be done. With this, even if the predetermined storage area is initialized when the supply of the operating power is started, the display content of the specific display means is displayed when notifying the determination result of the assignment determination means. It becomes the content. Therefore, even if the player confirms the display content of the specific display means when the supply of the operating power is started, it is possible to prevent whether or not the initialization of the predetermined storage area is performed. Become.

Features αI2. Setting means (57th to 57th) for setting a setting value to be used from among a plurality of setting values corresponding to the player's advantage in a settable situation that occurs when the supply of operating power is started. A function of executing the processing of step SC216 of the main CPU 63 in the 60th embodiment),
The initialization means initializes the predetermined storage area when the setting value of the usage target is set by the setting means or after the setting value of the usage target is set by the setting means. The gaming machine described in the feature αI1.

According to the characteristic αI2, when the setting value of the usage target is set when the supply of the operating power is started, or when the predetermined value is accompanyingly initialized when the setting value of the usage target is set, the usage target is set. When a new setting of the set value is performed, it becomes possible to start the game in a situation where a predetermined storage area is initialized. In this case, when the predetermined storage area is initialized in association with the new setting of the setting value to be used, the display data corresponding to the result used for notifying the determination result of the grant determination means is displayed and stored. Set to the area. With this, even if the predetermined storage area is initialized when the supply of the operating power is started, the display content of the specific display means is displayed when notifying the determination result of the assignment determination means. It becomes the content. Therefore, even if the player confirms the display content of the specific display means when the supply of the operating power is started, it may not be possible to specify whether or not a new setting of the setting value to be used is performed. It will be possible.

Features αI3. When the predetermined initialization condition is satisfied when the supply of the operating power is started (the information abnormality regarding the main RAM 65 does not occur, and the setting update display flag and the game stop flag are not set to "1"). In the case where the “RAM clear operation” is performed under the circumstances), another initialization unit (first unit) that initializes the predetermined storage area even when the setting value of the use target is not set by the setting unit 57 to 60th embodiment, a function of executing the first RAM clearing process of the main CPU 63),
The correspondence setting means sets the specific correspondence display data in the display storage area even when the predetermined storage area is initialized by the separate initialization means when the supply of operating power is started. Characteristic feature The gaming machine described in αI2.

According to the characteristic αI3, the predetermined storage area is initialized even when the setting value to be used is not set when the predetermined initialization condition is satisfied when the supply of the operating power is started. Therefore, it is possible to start the game in a situation where a predetermined storage area is initialized even in a situation where a new setting value of the use target is not set. In this case, regardless of whether the setting value to be used is newly set or the predetermined storage area is initialized by satisfying the predetermined initialization condition, Display data corresponding to the result used for notifying the determination result is set in the display storage area. As a result, the display of the specific display unit is displayed regardless of whether the new setting value of the use target is newly set or the predetermined storage area is initialized by the establishment of the predetermined initialization condition. The content is the display content displayed when notifying the determination result of the grant determination means. Therefore, even if the player confirms the display content of the specific display means when the supply of the operating power is started, whether or not a new setting of the set value to be used is performed and a predetermined initialization condition is satisfied. It becomes possible not to specify whether or not it has been done.

Features αI4. Among the display data corresponding to the result, the specific correspondence display data is display data used when the grant determining unit determines not to grant the privilege to the player. The gaming machine described in any one of αI3.

When the game hall is closed, it is usual that the power supply of the gaming machine is shut off in a situation where the display content corresponding to the decision not to give the privilege to the player has been displayed by the specific display means by the grant determination means. .. In this case, according to the characteristic αI4, when the predetermined storage area is initialized when the supply of the operating power is started, the display content of the specific display means does not give the privilege to the player in the addition determination means. The display content corresponds to the determined one. Thereby, even if the player confirms the display content of the specific display means when the supply of the operation power is started, the display content is the display content that was displayed before the supply of the operation power was stopped. With this, it becomes possible for the player to recognize, and it is possible to make it impossible to specify whether or not the initialization of a predetermined storage area has been performed.

Features αI5. There are multiple types of the specific correspondence display data,
The correspondence setting means sets, in the display storage area, the specific correspondence display data to be used from a plurality of types of specific correspondence display data, in any one of characteristics αI1 to αI4. Game machine.

According to the characteristic αI5, it is possible to diversify the display content of the specific correspondence display of the specific display means when the supply of the operating power is started.

Features αI6. The specific display control means, when the specific display is performed by the specific display means when the supply of the operating power is started, the specific display is performed after the specific display data is set in the display storage area. The gaming machine according to any one of features αI1 to αI5, characterized in that display of means is started.

According to the characteristic αI6, the display contents when the supply of the operating power is stopped before the supply of the operating power is stopped before the display of the specific correspondence is prevented from being performed by the specific display means. It becomes possible.

Features αI7. The processing for starting the supply of the operating power is executed when the supply of the operating power is started, and the processing for initializing the predetermined storage area by the initialization unit is performed when the supply of the operating power is started. The configuration included in the processing of
The characteristic display control means starts the display of the specific display means after the processing at the time of starting the supply of the operating power is executed when the supply of the operating power is started. Amusement machine.

According to the characteristic αI7, whether the predetermined storage area is initialized by the initialization means or not, the specific display means is provided at a timing after the process at the start of supplying the operating power is completed. It is possible to start the display at.

Features αI8. Setting means (57th to 57th) for setting a setting value to be used from among a plurality of setting values corresponding to the player's advantage in a settable situation that occurs when the supply of operating power is started. A function of executing the processing of step SC216 of the main CPU 63 in the 60th embodiment),
A configuration in which the initialization unit initializes the predetermined storage area when the setting value of the usage target is set by the setting unit or after the setting value of the usage target is set by the setting unit And
The gaming machine according to feature αI7, wherein the setting of the setting value of the use target by the setting means occurs in a situation where a process at the start of supply of the operating power is being executed.

According to the characteristic αI8, in the case where the setting value to be used is newly set or not set, in the specific display means at the timing after the process at the start of supplying the operating power is completed. It is possible to start the display.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features αI1 to αI8. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αJ group>
Features αJ1. Specific display means (special figure display section 37a, general figure display section 38a),
Display data setting means for setting display data in the display storage area (first display data buffer 271, third display data buffer 273) (in the 58th to 60th embodiments, the main CPU 63 executes the process of step SC717). Function for executing the process of step S8915 in the main CPU 63 in the sixty-first embodiment).
A specific display control means (a function of executing the processing of steps SC412 to SC414 in the main CPU 63) for controlling the display of the specific display means so that a display corresponding to the display data stored in the display storage area is performed; ,
Initialization means (58th to 58th) for initializing a predetermined storage area (clearing target area 371 in the 58th to 61st embodiments) including the display storage area based on the start of supply of operating power. 61, a function of executing the second RAM clearing process of the main CPU 63 in the embodiment 61),
Correspondence setting means for changing the display content of the specific display means to the specific correspondence display when the predetermined storage area is initialized by the initialization means when the supply of operating power is started (58th In the embodiment, the function of executing the processing of steps SC802 to SC805 in the main CPU 63, in the 59th embodiment, the function of executing the processing of steps SC902 to SC905 in the main CPU 63, and in the 60th embodiment, the main CPU 63. Function of executing the processing of steps SD102 to SD105, step SD109, step SD110, step SD113, and step SD114 in step 61, and a function of executing the processing of steps SD202 to SD217 in the main CPU 63 in the sixty-first embodiment).
Equipped with
A game machine characterized in that there are a plurality of types of the specific correspondence display.

According to the feature αJ1, it is possible to start the game in a situation where the predetermined storage area is initialized by initializing the predetermined storage area based on the start of the supply of the operating power. It will be possible. In this case, the display content of the specific display means when the supply of the operating power is started becomes the specific correspondence display. There are a plurality of types of the specific correspondence display. As a result, the display contents of the specific display means are diversified when the predetermined storage area is initialized. Therefore, even if the display content of the specific display means is confirmed when the supply of the operating power is started, it is possible to make it difficult to specify whether or not the predetermined storage area has been initialized.

Features αJ2. The correspondence setting means causes the specific display means to perform the specific correspondence display when the predetermined storage area is initialized by the initialization means when the supply of the operating power is started. Data is set in the display storage area,
The gaming machine according to feature αJ1, wherein there are a plurality of types of the specific correspondence display data.

According to the feature αJ2, when the predetermined storage area is initialized when the supply of the operating power is started, one of the plurality of types of specific correspondence display data is stored in the display storage area. By setting, the specific display is displayed by the specific display means. With this, it is possible to cause the specific display means to perform the specific correspondence display only by selecting one type of the specific correspondence display data from a plurality of predetermined types of the specific correspondence display data and setting it in the display storage area. Therefore, it is possible to simplify the processing configuration for causing the specific display means to perform one type of specific correspondence display among a plurality of types of specific correspondence displays.

Features αJ3. It is determined whether or not to give a privilege to the player, and when the privilege is given to the player, the privilege giving information (information of "1" set in the flag corresponding to the kind of the jackpot result) is given as above. An assignment determination means (a function of executing the process of step S508 in the main CPU 63) to be stored in the storage area;
A privilege granting unit for granting a privilege (opening/closing execution mode) to a player based on the privilege granting information stored in the predetermined storage area (a function of executing the processes of steps S408 to S412 in the main CPU 63). )When,
Equipped with
The display data setting means stores the display data (display data selected in step S507 or step S509) corresponding to the result determined by the grant determining means when the display timing of the determination result comes, in the display storage area. Set to
The specific display control means controls the display of the specific display means so that the display corresponding to the result-corresponding display data stored in the display storage area is performed, thereby responding to the determination result of the assignment determination means. The display is performed by the specific display means,
The gaming machine according to feature αJ2, wherein the specific correspondence display data is display data used as the result correspondence display data.

According to the feature αJ3, since the display corresponding to the determination result of whether or not to give the privilege to the player is performed by the specific display means, the player pays attention to the specific display means. In this case, when the supply of the operating power is started by using the display data corresponding to the result used for notifying the determination result of the grant determination means, the specific correspondence display is performed by the specific display means. As a result, whether or not the predetermined storage area is initialized even if the player confirms the display content of the specific display means when the supply of the operating power is started while suppressing the increase in the capacity of the display data. It is possible to make it difficult to specify whether or not.

Features αJ4. Among the display data corresponding to the result, the specific correspondence display data is display data used when the grant determination means determines not to grant the privilege to the player. The game machine described.

When the game hall is closed, it is usual that the power supply of the gaming machine is shut off in a situation where the display content corresponding to the decision not to give the privilege to the player has been displayed by the specific display means by the grant determination means. .. In this case, according to the characteristic αJ4, even if the predetermined storage area is initialized when the supply of the operating power is started, the display content of the specific display means does not give the privilege to the player in the addition determination means. The displayed content corresponds to the determination made. Thereby, even if the player confirms the display content of the specific display means when the supply of the operation power is started, the display content is the display content that was displayed before the supply of the operation power was stopped. With this, it becomes possible for the player to recognize, and it is possible to make it impossible to specify whether or not a predetermined storage area has been initialized.

Features αJ5. Among the display data corresponding to the result, the specific correspondence display data is display data used when the grant determination means determines not to grant the privilege to the player, and the display data corresponding to the player in the grant determination means. The gaming machine according to feature αJ3, which includes both display data used when it is determined to grant the privilege.

According to the characteristic αJ5, in the display and the grant determination means when the predetermined storage area is initialized when the supply of the operating power is started, the grant determination means determines that the privilege is not granted to the player Any of the displays in the case where it is determined to give a privilege to the player is performed by the specific display means as the specific correspondence display. Thereby, even if the player confirms the display content of the specific display means when the supply of the operation power is started, the display content is the display content that was displayed before the supply of the operation power was stopped. With this, it becomes possible for the player to recognize, and it is possible to make it impossible to specify whether or not a predetermined storage area has been initialized.

Features αJ6. Setting means for setting a setting value to be used from setting values of a plurality of levels corresponding to the player's advantage in a setting possible situation generated based on the start of supply of operating power (58th to A function of executing the processing of step SC216 of the main CPU 63 in the 61st embodiment),
The initialization means initializes the predetermined storage area when the setting value of the usage target is set by the setting means or after the setting value of the usage target is set by the setting means. The gaming machine according to any one of the features αJ1 to αJ5.

According to the characteristic αJ6, when the setting value of the usage target is set when the supply of the operating power is started, or when the predetermined value is accompanyingly initialized when the setting value of the usage target is set, the usage target is set. When a new setting of the set value is performed, it becomes possible to start the game in a situation where a predetermined storage area is initialized. In this case, when the predetermined storage area is initialized in association with the new setting of the setting value to be used, one of the plurality of types of specific correspondence display is displayed by the specific display means. Done. As a result, the display contents of the specific display means are diversified when the setting value of the use target is newly set, and the player displays the specific display means when the supply of the operating power is started. Even if the contents are confirmed, it is possible to make it impossible to specify whether or not a new setting of the setting value to be used is performed.

Features αJ7. When the predetermined initialization condition is satisfied when the supply of the operating power is started (the information abnormality regarding the main RAM 65 does not occur, and the setting update display flag and the game stop flag are not set to "1"). In the case where the "RAM clear operation" is performed under the circumstances), another initialization means (58th to 58th) for initializing the predetermined storage area even when the setting value is not set by the setting means. 61, a function of executing the first RAM clearing process of the main CPU 63 in the embodiment of FIG.
The correspondence setting means uses the setting means when the predetermined storage area is initialized by the separate initialization means when the supply of the operating power is started and when the supply of the operating power is started. The gaming machine according to feature αJ6, characterized in that the display content of the specific display means is set to a specific correspondence display when the target setting value is set.

According to the characteristic αJ7, the predetermined storage area is initialized even when the setting value is not set when the predetermined initialization condition is satisfied when the supply of the operating power is started. Even if the setting value is not newly set, it is possible to start the game with the predetermined storage area initialized. In this case, the specific display means displays the specific correspondence whether the new setting value is set or the predetermined storage condition is initialized by the predetermined initialization condition. Done. Thereby, even if the player confirms the display content of the specific display means when the supply of the operating power is started, whether or not a new setting of the set value is performed and whether a predetermined initialization condition is satisfied. It becomes possible not to specify whether or not.

Features αJ8. The correspondence setting means sets the display content of the specific display means to the specific correspondence display even when the predetermined storage area is not initialized by the initialization means when the supply of the operating power is started. The gaming machine according to any one of the features αJ1 to αJ7.

According to the feature αJ8, the specific display means performs the specific correspondence display both when the predetermined storage area is initialized and when it is not initialized when the supply of the operating power is started. With this, even if the player confirms the display content of the specific display means when the supply of the operating power is started, it is impossible to specify whether or not the predetermined storage area is initialized by the initialization means. It becomes possible to do.

Features αJ9. The correspondence setting means is capable of supplying operating power in a predetermined regulation situation (during game times, opening/closing execution mode, variable display times on the universal display section 38a, and normal power open state). Specific correspondence display data for performing the specific correspondence display when the predetermined storage area is not initialized by the initialization means when the supply of the operating power is started after that The game machine according to feature αJ8, wherein is not set in the display storage area.

According to the characteristic αJ9, when the supply of the operating power is stopped in the predetermined regulation situation and the supply of the operating power is started after that, the predetermined storage area is not initialized, the display storage area Since the specific correspondence display data is not set in, the display data when the supply of the operating power is stopped is stored and held in the display storage area as it is. With this, when the supply of the operating power is stopped in the predetermined regulation situation, and when the supply of the operating power is subsequently started and the predetermined storage area is not initialized, the supply of the operating power is stopped. The display of the specific display means can be started from the display content of the specific display means when the display is stopped.

Features αJ10. The specific display control means controls the display of the specific display means such that a display corresponding to the determination result of the assignment determination means is performed after the variable display of the pattern is started,
The correspondence setting means is initialized when the supply of the operating power is stopped in a situation where the variable display of the pattern is being displayed on the specific display means and then the supply of the operating power is started. The gaming machine according to the feature αJ8 or αJ9, wherein specific correspondence display data for performing the specific correspondence display is not set in the display storage region when the predetermined storage region is not initialized by the means. ..

According to the characteristic αJ10, the predetermined storage area is obtained when the supply of the operating power is stopped in the situation where the variable display of the pattern is being performed by the specific display means and the supply of the operating power is started thereafter. Since the specific correspondence display data is not set in the display storage area when is not initialized, the display data when the supply of the operating power is stopped is stored and held as it is in the display storage area. As a result, the predetermined storage area is initialized when the supply of the operating power is stopped in the situation where the variable display of the pattern is being performed by the specific display means and the supply of the operating power is started thereafter. If not, it is possible to restart the variable display of the pattern on the specific display means.

Features αJ11. When the privilege grant information is stored in the predetermined storage area, the privilege granting unit grants the privilege after the display corresponding to the privilege granting is displayed on the specific display unit. Is something
The correspondence setting unit is configured to perform the initialization by the initialization unit when the supply of the operating power is stopped in a situation where the privilege is provided by the privilege providing unit and the supply of the operating power is subsequently started. The game according to any one of the features αJ8 to αJ10, wherein specific correspondence display data for performing the specific correspondence display is not set in the display storage region when a predetermined storage area is not initialized. Machine.

According to the feature αJ11, when the supply of the operating power is stopped in the situation where the privilege is given and the supply of the operating power is started after that, the predetermined storage area is not initialized. Since the specific correspondence display data is not set in the display storage area, the display data when the supply of the operating power is stopped is stored and held as it is in the display storage area. As a result, when the supply of the operating power is stopped in the situation where the privilege is granted, and when the supply of the operating power is started after that, the predetermined storage area is not initialized, It becomes possible to start the display of the specific display means from the display content corresponding to the situation in which is added.

Features αJ12. The specific display control means starts the display of the specific display means in the state in which the specific correspondence display is performed when the specific correspondence display is performed by the specific display means when the supply of the operating power is started. The gaming machine according to any one of the features αJ1 to αJ11.

According to the feature αJ12, the display content when the supply of the operating power is stopped before the specific correspondence display is performed when the supply of the operating power is started is prevented from being performed by the specific display means. It becomes possible.

Features αJ13. The processing for starting the supply of the operating power is executed when the supply of the operating power is started, and the processing for initializing the predetermined storage area by the initialization unit is performed when the supply of the operating power is started. The configuration included in the processing of
A characteristic αJ12 characterized in that the specific display control means starts the display of the specific display means after the processing at the time of starting the supply of the operating power is executed when the supply of the operating power is started. Amusement machine.

According to the feature αJ13, whether the predetermined storage area is initialized by the initialization means or not, the specific display means is provided at a timing after the process at the start of supplying the operating power is completed. It is possible to start the display at.

Features αJ14. Setting means for setting a setting value to be used from setting values of a plurality of levels corresponding to the player's advantage in a setting possible situation generated based on the start of supply of operating power (58th to A function of executing the processing of step SC216 of the main CPU 63 in the 61st embodiment),
A configuration in which the initialization unit initializes the predetermined storage area when the setting value of the usage target is set by the setting unit or after the setting value of the usage target is set by the setting unit And
The game machine according to feature αJ13, wherein the setting of the setting value of the use target by the setting unit occurs in a situation where the process at the start of supplying the operating power is being executed.

According to the feature αJ14, in the case where the setting value to be used is newly set and the case where the setting value is not set, the specific display means is set at the timing after the process at the start of supplying the operating power is completed. It is possible to start the display.

In addition, with respect to the configurations of the features αJ1 to αJ14, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, and features βA1 to βA. 4. Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αK group>
Features αK1. Specific display means (special figure display section 37a, general figure display section 38a),
It is determined whether or not to give a bonus to the player, and when the bonus is given to the player, the bonus giving information (the information of "1" set in the flag corresponding to the kind of the jackpot result) is stored in a predetermined memory. An assignment determination unit (a function of the main CPU 63 that executes the process of step S508) to be stored in the area (the clear target area 371 in the 61st embodiment);
A privilege granting unit for granting a privilege (opening/closing execution mode) to a player based on the privilege granting information stored in the predetermined storage area (a function of executing the processes of steps S408 to S412 in the main CPU 63). )When,
When the display timing of the determination result is reached, the display data corresponding to the determination result of the assignment determination means (display data selected in step S507 or step S509) is stored in the display storage area (first display data buffer 271, Display data setting means (function of executing the process of step S8915 in the main CPU 63) set in the third display data buffer 273);
By controlling the display of the specific display means so that the display corresponding to the result-corresponding display data stored in the display storage area is performed, the display corresponding to the determination result of the grant determination means is the specific display means. Specific display control means (a function of executing the processing of steps SC412 to SC414 in the main CPU 63),
Initialization means (mainly in the 61st embodiment) for initializing a predetermined storage area including the display storage area (clear target area 371 in the 61st embodiment) based on the start of supply of operating power. Function of executing the second RAM clearing process of the side CPU 63),
Correspondence setting means (main CPU 63) for setting the display content of the specific display means to be the specific correspondence display when the predetermined storage area is initialized by the initialization means when the supply of the operating power is started. Function for executing the processing of steps SD202 to SD217) in
Equipped with
There are multiple types of specific correspondence display,
A game machine characterized in that the plurality of types of the specific correspondence display include display contents that are not selected as a display corresponding to the determination result of the grant determination means.

According to the characteristic αK1, it is possible to start the game in a situation where the predetermined storage area is initialized by initializing the predetermined storage area based on the start of the supply of the operating power. It will be possible. In this case, the display content of the specific display means when the supply of the operating power is started becomes the specific correspondence display. There are a plurality of types of the specific correspondence display, and the plurality of types of specific correspondence displays include display contents that are not selected as the display corresponding to the determination result of the grant determination means. As a result, the display contents of the specific display means are diversified when the predetermined storage area is initialized. Therefore, even if the display content of the specific display means is confirmed when the supply of the operating power is started, it is possible to make it difficult to specify whether or not the predetermined storage area has been initialized.

Features αK2. The plurality of types of the specific correspondence display include display content that can be selected as a display corresponding to the determination result of the grant determination means, and display content that is not selected as a display corresponding to the determination result of the grant determination means. The gaming machine described in the feature αK1.

According to the characteristic αK2, since the plurality of types of specific correspondence displays include both the display contents that can be selected and the display contents that are not selected as the display corresponding to the determination result of the grant determination unit, the predetermined storage area is initially set. It is possible to diversify the display contents of the specific display means in the case of being liquefied.

Features αK3. The specific display means has a plurality of light emitting units,
The correspondence setting means performs a lottery process (step SD204, step SD212) as to whether or not to individually turn on each of the plurality of light emitting units, and a result of the lottery process for each of the plurality of light emitting units. The gaming machine according to the feature αK1 or αK2, wherein the display data of the lighting pattern corresponding to is set in the display storage area so that the specific correspondence display is performed.

According to the feature αK3, the lottery process for determining whether or not each of the plurality of light emitting units in the specific display means is turned on is executed, and the display content of the lighting pattern corresponding to the result of the lottery process is stored in the predetermined storage area. Is displayed on the specific display means as a specific correspondence display when the is initialized. This makes it possible to diversify the display contents of the specific display means when the predetermined storage area is initialized, and to prevent the display contents of the specific display means when the predetermined storage area is initialized. It becomes possible to be regular.

Features αK4. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the advantage of the player in a setting possible situation that occurs when the supply of operating power is started (61st setting) A function of executing the process of step SC216 of the main CPU 63 in the embodiment),
The initialization unit initializes the predetermined storage area when the setting value of the use target is set by the setting unit or after the setting value of the use target is set by the setting unit. The gaming machine according to any one of the features αK1 to αK3.

According to the feature αK4, when the setting value of the usage target is set when the supply of the operating power is started, or when the predetermined value is accompanyingly initialized when the setting value of the usage target is set, the usage target is set. When a new setting of the set value is performed, it becomes possible to start the game in a situation where a predetermined storage area is initialized. In this case, when the predetermined storage area is initialized in association with the new setting of the setting value to be used, one of the plurality of types of specific correspondence display is displayed by the specific display means. Done. As a result, the display contents of the specific display means are diversified when the setting value of the use target is newly set, and the player displays the specific display means when the supply of the operating power is started. Even if the contents are confirmed, it is possible to make it impossible to specify whether or not a new setting of the setting value to be used is performed.

Features αK5. When the predetermined initialization condition is satisfied when the supply of the operating power is started (the information abnormality regarding the main RAM 65 does not occur, and the setting update display flag and the game stop flag are not set to "1"). In the case where the “RAM clear operation” is performed under the circumstances), another initialization unit (first unit) that initializes the predetermined storage area even when the setting value of the use target is not set by the setting unit 61, a function of executing the first RAM clearing process of the main CPU 63 in the embodiment of FIG.
The correspondence setting means uses the setting means when the predetermined storage area is initialized by the separate initialization means when the supply of the operating power is started and when the supply of the operating power is started. The gaming machine according to feature αK4, wherein the display content of the specific display means is set to a specific correspondence display in any case where the target setting value is set.

According to the characteristic αK5, the predetermined storage area is initialized even when the setting value is not set when the predetermined initialization condition is satisfied when the supply of the operating power is started. Even if the setting value is not newly set, it is possible to start the game with the predetermined storage area initialized. In this case, the specific display means displays the specific correspondence whether the new setting value is set or the predetermined storage condition is initialized by the predetermined initialization condition. Done. Thereby, even if the player confirms the display content of the specific display means when the supply of the operating power is started, whether or not a new setting of the set value is performed and whether a predetermined initialization condition is satisfied. It becomes possible not to specify whether or not.

Features αK6. The specific display control means starts the display of the specific display means in the state in which the specific correspondence display is performed when the specific correspondence display is performed by the specific display means when the supply of the operating power is started. The gaming machine according to any one of the features αK1 to αK5.

According to the characteristic αK6, the display content when the supply of the operating power is stopped before the display of the specific correspondence when the supply of the operating power is started is prevented from being performed by the specific display means. It becomes possible.

Features αK7. The processing for starting the supply of the operating power is executed when the supply of the operating power is started, and the processing for initializing the predetermined storage area by the initialization unit is performed when the supply of the operating power is started. The configuration included in the processing of
The characteristic display control unit starts the display of the specific display unit after the process at the time of starting the supply of the operating power is executed when the supply of the operating power is started. Amusement machine.

According to the characteristic αK7, whether the predetermined storage area is initialized by the initialization means or not, the specific display means is performed at a timing after the process at the start of supplying the operating power is completed. It is possible to start the display at.

Features αK8. Setting means for setting a setting value to be used from setting values of a plurality of stages corresponding to the player's advantage in a setting possible situation generated based on the start of supply of operating power (56th The function of executing the processing of step SC216 of the main CPU 63 in the embodiment),
A configuration in which the initialization unit initializes the predetermined storage area when the setting value of the usage target is set by the setting unit or after the setting value of the usage target is set by the setting unit And
The gaming machine according to feature αK7, wherein the setting of the setting value of the use target by the setting unit occurs in a situation where a process at the start of supplying the operating power is being executed.

According to the feature αK8, whether the new setting of the setting value to be used is performed or not, the specific display means displays the timing after the process at the start of supplying the operating power is completed. It is possible to start the display.

In addition, with respect to the configurations of the features αK1 to αK8, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the inventions related to the characteristic αF group, the characteristic αG group, the characteristic αH group, the characteristic αI group, the characteristic αJ group, and the characteristic αK group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, it is necessary to make the operation at the time of starting the supply of the operating power suitable, and there is still room for improvement in this respect.

<Characteristic αL group>
Features αL1. Specific display means (special figure display section 37a, general figure display section 38a),
A specific display control means for controlling the display of the specific display means (a function of executing the processing of steps SC412 to SC414 in the main CPU 63);
Setting means for setting a setting value to be used among setting values of a plurality of stages corresponding to the player's advantage in a settable situation generated based on the start of supply of operating power (62nd to A function of executing the process of step SC216 of the main CPU 63 in the 63rd embodiment),
Equipped with
The specific display control means is that the setting value to be used is set by the setting means, and the setting value or operation is equal to or higher than the advantage of the setting value before the supply of operating power is stopped. Based on the fact that a setting value that is more advantageous than the setting value before the power supply is stopped is set by the setting means as the setting value that is the usage target, which is one of the suggestion target situations , A mode of determining the display content of the specific display means when the supply of the operating power is started (a mode of referring to the second display allocation table 392 for special figures, a mode for general figures) 2 Mode distribution means (mode of referring to the display distribution table 394) (function for executing the processes of steps SD402 to SD411 in the main CPU 63 in the 62nd embodiment, the main CPU 63 in the 63rd embodiment) A game machine having a function of executing the processing of step SD502).

According to the characteristic αL1, by confirming the display content of the specific display means when the supply of the operating power is started, the setting value to be used is newly set or the setting to be used is made. It is possible to predict that the advantage of the value is equal to or higher than the advantage of the previously set value or higher than the advantage of the previously set value. As a result, it becomes possible to make the player predict the set value by using the display content of the specific display means, and it is possible to improve the interest of the game.

Feature αL2. The aspect determining means is configured such that the set value that is equal to or higher than the advantage of the set value before the supply of the operating power is stopped or the set value that is more advantageous than the set value before the supply of the operating power is stopped is The display content of the specific display means when the supply of the operating power is started on the basis of being set by the setting means as the setting value to be used is determined in a determination mode corresponding to the suggestion target situation, and the operation is performed. In the case where the supply of the operating power is started based on the fact that the setting value lower than the advantage of the setting value before the power supply is stopped is set by the setting means as the setting value to be used. A mode of determining the display content of the specific display means corresponding to a non-indication target situation (a mode of referring to the first display allocation table 391 for special drawings, a mode of referring to the first display allocation table 393 for general drawings) The gaming machine described in the feature αL1, which is characterized by being determined by.

According to the characteristic αL2, the determination mode corresponding to the suggestion target situation when the advantage of the set value to be used is equal to or higher than the advantage of the set value up to that point or higher than the advantage of the set value up to that point In the case where the display content of the specific display means is determined, and when the advantage of the set value to be used becomes lower than the set value up to then, the specific display means of the specific display means is determined in a determination mode corresponding to the non-indication target situation. The display content is determined. As a result, it becomes easy to predict whether or not the advantage of the set value to be used is equal to or higher than the advantage of the set value up to that point or higher than the advantage of the set value up to that point.

Feature αL3. The mode determining means sets the display content of the specific display means when the supply of operating power is started based on the fact that the setting value to be used is not set by the setting means to the non-indication target. The gaming machine according to feature αL2, which is determined in a determination mode corresponding to a situation.

According to the characteristic αL3, the supply of the operating power is started in the determination mode corresponding to the non-indication target situation even when the setting value to be used is not newly set when the supply of the operating power is started. When the display content of the specific display means is determined in a determination mode corresponding to the non-indication target situation, the situation is changed to a new setting value to be used. It is possible to make it impossible to identify whether the setting is not performed or the setting value to be used is less advantageous than before.

Features αL4. Any one of the characteristics αL1 to αL3 characterized in that the aspect determining means determines the display content of the specific display means by lottery in a lottery manner corresponding to the suggestion target situation when the suggestion target situation is the suggestion target situation. Gaming machine described in.

According to the feature αL4, it is possible to diversify the display content of the specific display means in the suggestion target situation. As a result, even if the specific display means is confirmed, it is possible not to clearly specify whether or not the situation is the suggestion target situation.

Features αL5. The aspect determining means determines the display content of the specific display means by lottery in a lottery manner corresponding to the non-indication target situation when the non-indication target situation is not the suggestion target situation The gaming machine described in αL4.

According to the feature αL5, it is possible to diversify the display content of the specific display means in the non-indication target situation. As a result, even if the specific display means is confirmed, it is possible not to clearly specify whether or not the situation is the non-indication target situation.

Features αL6. Display contents that can be selected in a lottery of display contents of the specific display means by a lottery mode corresponding to the suggestion target situation and selection by display lottery of display contents of the specific display means in a lottery mode corresponding to the non-indication target situation There is common display content (first to third initial display for special drawings, first to third initial display for general drawings) in any of the display contents that can be displayed, and the selection probability of the common display content is The gaming machine according to feature αL5, which is different in a lottery mode corresponding to the suggestion target situation and a lottery mode corresponding to the non-indication target situation.

According to the feature αL6, the common display content is displayed on the specific display means regardless of whether the suggestion target situation or the non-indication target situation, and therefore it is clear which of the suggestion target situation and the non-indication target situation. It is possible to make it impossible to specify. On the other hand, since the selection probability of the common display content is different in the suggestion target situation and the non-indication target situation, the display content of the specific display means indicates whether the suggestion target situation or the non-indication target situation. It becomes possible to predict whether there is any.

Features αL7. Display data setting means for setting display data in the display storage area (function of executing the process of step S8915 in the main CPU 63),
The specific display control means controls the display of the specific display means so that a display corresponding to the display data stored in the display storage area is performed.
Initialization in the case where the setting value of the use target is set by the setting means or after the setting value of the use target is set by the setting means, initialization of a predetermined storage area including the display storage area The gaming machine according to any one of the features αL1 to αL6, which is provided with means (a function of executing the second RAM clearing process of the main CPU 63 in the 62nd to 63rd embodiments).

According to the feature αL7, when the setting value of the usage target is set when the supply of the operating power is started, or when the predetermined value is accompanyingly initialized when the setting value of the usage target is set, the usage target is set. When a new setting of the set value is performed, it becomes possible to start the game in a situation where a predetermined storage area is initialized. In this case, by providing the configuration of the characteristic αL1, the situation in which the display storage area is initialized along with the initialization of the predetermined storage area is used, and the indication target situation is indicated by the display content of the specific display means. It is possible to predict whether or not

Feature αL8. When a predetermined initialization condition is satisfied when supply of operating power is started (information abnormality regarding the main RAM 65 does not occur, and "1" is not set in the setting update display flag and the game stop flag. When a "RAM clear operation" is performed in a situation), another initialization means for initializing the predetermined storage area (function of executing the first RAM clear processing of the main CPU 63 in the 62nd to 63rd embodiments). Equipped with
The aspect determination means determines, when the predetermined storage area is initialized by the different initialization means, the display content of the specific display means when the supply of the operating power is started corresponding to the non-indication target situation. The gaming machine described in the feature αL7, which is determined by a mode.

According to the characteristic αL8, since the predetermined storage area is initialized when the predetermined initialization condition is satisfied when the supply of the operating power is started, the game is performed in the situation where the predetermined storage area is initialized. Can be started. In this case, when the predetermined storage area is initialized by the separate initialization means, the display content of the specific display means when the supply of the operating power is started is determined in a determination mode corresponding to the non-indication target situation. Therefore, it becomes easy to predict whether or not the situation is a suggestion target.

Features αL9. It is determined whether or not to give a bonus to the player, and when the bonus is given to the player, the bonus giving information (the information of "1" set in the flag corresponding to the kind of the jackpot result) is stored in a predetermined memory. An assignment determination means (a function of executing the process of step S508 in the main CPU 63) to be stored in the area;
A privilege granting unit for granting a privilege (opening/closing execution mode) to a player based on the privilege granting information stored in the predetermined storage area (a function of executing the processes of steps S408 to S412 in the main CPU 63). )When,
Equipped with
The gaming machine according to any one of features αL1 to αL8, wherein the specific display control unit causes the display corresponding to the determination result of the grant determination unit to be performed by the specific display unit.

According to the characteristic αL9, the player pays attention to the specific display means by the display corresponding to the determination result of whether or not to give a privilege to the player, by the specific display means. In this case, by providing the configuration of the above characteristic αL1, it becomes possible to obtain the excellent effects as described above by utilizing the specific display means.

Feature αL10. The display content of the specific display means determined in the determination mode corresponding to the suggestion target situation is display content that is not displayed when the display corresponding to the determination result of the grant determination means is performed by the specific display means. The gaming machine described in the feature αL9.

According to the feature αL10, it is possible to distinguish the display content determined in the determination mode corresponding to the suggestion target situation from the display content corresponding to the determination result of the assignment determination means.

Feature αL11. The specific display control means, when the display according to the display content determined by the mode determining means is performed by the specific display means when the supply of the operating power is started, the display content determined by the mode determining means. The gaming machine according to any one of the features αL1 to αL10, characterized in that the display of the specific display means is started in a state where the display is performed.

According to the characteristic αL11, when the supply of the operating power is started, the display of the display content when the supply of the operating power is stopped before the display according to the display content determined by the mode determining means is performed is the specific display means. It is possible to prevent it from happening in.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features αL1 to αL11. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, and features βA1 to βA. 4. Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the characteristic αL group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, it is necessary to improve the interest of the game, and there is still room for improvement in this respect.

<Characteristic αM group>
Features αM1. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (function of executing the process of step SB311 in the main CPU 63),
Corresponding operation control means for setting the state of a predetermined region visible from the front of the gaming machine as the corresponding operation state in the situation where the predetermined setting-related processing (setting value updating processing, setting confirmation processing) relating to the setting value is being executed. (In the 64th embodiment, the function of executing the processing of steps SE304, SE305, SE308, and SE309 in the main CPU 63; in the 65th embodiment, the function of executing the processing of step SE604 and step SE607 in the main CPU 63. In the sixty-sixth embodiment, the function of executing steps SE704, SE707, SE802 and SE816 in the main CPU 63, and in the sixty-sixth embodiment, the function of executing steps SE904 and SE907 in the main CPU 63. In the sixty-eighth embodiment, a function of controlling display of the 15R display unit 481, the 6R display unit 483, and the small hit display unit 484 in the main CPU 63),
A gaming machine characterized by being equipped with.

According to the feature αM1, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player is allowed to use the more advantageous setting value. Will be expected. In this case, in a situation where a predetermined setting-related process relating to the set value is being executed, the state of the predetermined region which can be visually recognized from the front of the gaming machine is the corresponding operation state. This allows the manager of the game hall to easily understand whether or not a predetermined setting-related process is being executed.

Features αM2. Predetermined operation means (in the 65th embodiment, a universal figure display section 423a, a first special figure display section 425, a second special figure display section 426, and a special display section which are provided in the predetermined area visible from the front of the gaming machine. 429, in the 67th embodiment, a first special figure display unit 425 and a second special figure display unit 426),
In the situation where the predetermined setting-related processing is being executed, the corresponding operation control means sets the operation state of the predetermined operation means to an operation state that does not occur when a game is being executed, so that the predetermined area The gaming machine according to feature αM1, wherein the state is set to the corresponding operation state.

According to the feature αM2, the operation state of the predetermined operation means in the situation where the predetermined setting-related processing is executed is an operation state that does not occur when the game is executed. Thereby, it becomes possible to execute the notification indicating that the predetermined setting-related processing is being executed by using the predetermined operation means that operates when the game is being executed.

Features αM3. A plurality of predetermined operation means (in the 64th embodiment, a first special figure display portion 425, a second special figure display portion 426, a special display portion 429, and a 65th embodiment) in the predetermined area that can be viewed from the front of the gaming machine. Then, the public figure display unit 423a, the general figure reservation display unit 423b, the first special figure display unit 425, the second special figure display unit 426, the first special figure reservation display unit 427, the second special figure reservation display unit 428, and the special display. Section 429, the special electric prize winning device 416, the first special figure display section 425 and the second special figure display section 426 in the 66th embodiment, and the 15R display section 481, 6R display section 483 and the small hit display section in the 68th embodiment. 484),
The gaming machine according to feature αM1 or αM2, wherein the corresponding operation control means sets a combination of operating states of the plurality of predetermined operating means as the corresponding operating state.

According to the feature αM3, the notification indicating that the predetermined setting-related processing is being executed is executed by using the combination of the operation states of the plurality of predetermined operation means. As a result, it becomes possible to make it difficult to perform an act of illegally issuing a notification indicating that a predetermined setting-related process is being executed.

Features αM4. The gaming machine according to feature αM3, wherein the corresponding operating state is an operating state of a combination that does not occur when a game is being executed among a combination of operating states of the plurality of predetermined operating means.

According to the feature αM4, the combination of the operation states of the plurality of predetermined operation means is a combination that does not occur when the game is being executed, thereby indicating that the predetermined setting-related processing is being executed. Is executed. As a result, it becomes possible to execute a notification indicating that a predetermined setting-related process is being executed by using a plurality of predetermined operation means that operate when a game is being executed.

Features αM5. Each individual operating state in the corresponding operating state of the plurality of predetermined operating means is an operating state that can occur when a game is being executed, while those individual operating states occur simultaneously when the game is being executed. The gaming machine according to feature αM4, which is in a non-operating state.

According to the characteristic αM5, the individual operation states in the corresponding operation states of the plurality of predetermined operation means are the operation states that can occur when the game is being executed, and thus occur when the game is being executed. By using the obtained operating state, it is possible to execute the notification indicating that the predetermined setting-related processing is being executed.

Features αM6. The gaming machine according to any one of the features αM3 to αM5, wherein the first predetermined operating unit is a display unit and the second predetermined operating unit is a movable unit among the plurality of predetermined operating units.

According to the characteristic αM6, since the notification indicating that the predetermined setting-related processing is being executed is made by the combination of the individual operation states of the display means and the movable means, the predetermined setting-related processing is executed. It becomes easier to understand that the situation is

Features αM7. The corresponding operation control means,
In a situation in which the first setting-related processing is being executed as the predetermined setting-related processing, a first corresponding operation control means for setting a combination of the operation states of the plurality of predetermined operation means as the corresponding operation state to be the first corresponding operation state. (In the 64th embodiment, the main CPU 63 executes the processing of steps SE 304 and SE 305; in the 65th embodiment, the main CPU 63 executes the processing of step SE 604; in the 66th embodiment, the main CPU A function of executing the processing of step SE704, step SE802 and step SE816 in the CPU 63, and a function of displaying and controlling the 15R display portion 481 and the small hit display portion 484 in the main CPU 63 in the 68th embodiment),
In a situation where the second setting-related processing is executed as the predetermined setting-related processing, a second corresponding operation control means for setting a combination of the operation states of the plurality of predetermined operation means as the second corresponding operation state as the corresponding operation state. (In the 64th embodiment, the function of executing the processing of steps SE308 and SE309 in the main CPU 63; in the 65th embodiment, the function of executing the processing of step SE 607 in the main CPU 63; A function of executing the processing of step SE707, step SE802 and step SE816 in the CPU 63, a function of displaying and controlling the 15R display portion 481 and the 6R display portion 483 in the main CPU 63 in the sixty-eighth embodiment),
The gaming machine according to any one of the features αM3 to αM6.

According to the feature αM7, a notification that the first setting-related process is being executed and a state where the second setting-related process is being executed are made by using the combination of the operation states of the plurality of predetermined operation means. It becomes possible to execute each of the notifications.

Features αM8. The first setting-related processing is processing that enables the setting means to set the setting value to be used,
The gaming machine according to feature αM7, wherein the second setting-related processing is processing for notifying the current setting value.

According to the characteristic αM8, the notification that the processing is being executed that enables the setting of the setting value to be used by using the combination of the operation states of the plurality of predetermined operation means, and the object to be used is set. It is possible to execute each of the notifications that the process for making the setting value notified is being executed.

For the configurations of the features αM1 to αM8, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αN group>
Features αN1. A first period generating means (a function of executing the processes of steps SD815 and SD816 in the main CPU 63) that causes a first period (game time) in a situation where a game is being executed;
A first predetermined operation means (first special figure display section 425, second special figure display section 426) is controlled so as to be in a state corresponding to the first period (state in which variable display of patterns is performed) in the first period. 1 predetermined operation control means (function of executing the processing of step SD706 in the main CPU63),
Second period generation means (function of executing the processes of step SD904 and step SE116 in the main CPU 63) that causes the second period (opening/closing execution mode) in the situation where the game is being executed,
Second predetermined operation control means (main CPU 63, steps SD710 to SD712) for controlling the second predetermined operation means (special electric prize winning apparatus 416) so as to be in the second period corresponding state (open state) in the second period. Function to execute)
Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (function of executing the process of step SB311 in the main CPU 63),
In a situation where a predetermined setting-related process (setting value update process, setting confirmation process) relating to the set value is being executed, the first predetermined operating means is in the state corresponding to the first period, and the second predetermined operating means is A corresponding operation control means (a function of executing the processing of step SE704, step SE707, step SE802, and step SE816 in the main CPU 63) for setting the second period corresponding state;
A gaming machine characterized by being equipped with.

According to the characteristic αN1, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player is allowed to use the more advantageous setting value. Will be expected. In this case, a first period in which the first predetermined operation means is in the first period corresponding state may occur in the situation where the game is being executed, and a second period in which the second predetermined operation means is in the second period corresponding state is In a configuration that can occur, the first predetermined operation means is in the first period corresponding state and the second predetermined operation means is in the second period corresponding state in the situation where the predetermined setting related processing regarding the set value is executed. Thereby, it is possible to execute a notification indicating that a predetermined setting-related process is being executed by using the first predetermined operation means and the second predetermined operation means that operate when the game is being executed. It will be possible.

In addition, it is possible to execute a notification indicating that a predetermined setting-related process is being executed by using the first period corresponding state and the second period corresponding state that can occur when a game is being executed. It will be possible. Further, when it is attempted to illicitly notify that the predetermined setting-related processing is being executed, it is necessary to illegitimate both the first predetermined operation means and the second predetermined operation means. There is. Therefore, it becomes possible to make it difficult to carry out an act of illegally giving a notification indicating that a predetermined setting-related process is being executed.

Features αN2. The gaming machine according to feature αN1, wherein the second period generating means causes the second period to occur after the first period.

According to the characteristic αN2, in the situation where the game is being played, the second period occurs after the first period, so the first predetermined operation means is in the first period corresponding state and the second predetermined operation means is in the second period. In the case of the corresponding state, it is possible to give the manager of the game hall the recognition that it is a special situation different from the situation in which the game is being played. This makes it possible for the manager of the game hall to clearly recognize that the predetermined setting-related processing regarding the set value is being executed.

Features αN3. One of the first predetermined operation means and the second predetermined operation means is a display means and the other is a movable means, the gaming machine according to the feature αN1 or αN2.

According to the characteristic αN3, since the notification indicating that the predetermined setting-related processing is being executed is performed by the combination of the period corresponding states of the display means and the movable means, the predetermined setting-related processing is executed. It becomes easier to understand that the situation is

Features αN4. A means for executing a period lottery for determining whether or not to generate the second period after the first period (function of executing the process of step SD803 in the main CPU 63),
The first predetermined operation control means is configured to notify the result of the period lottery after setting the first predetermined operation means to the first period corresponding state in the first period,
When the result of the period lottery is a result that causes the second period, the second predetermined operation control means sets the second period corresponding state after the first period ends. 2. The gaming machine according to any one of the features αN1 to αN3, which controls a predetermined operation means.

According to the feature αN4, the predetermined predetermined operation means for notifying the result of the period lottery and the second predetermined operation means which becomes the second period corresponding state when the result of the period lottery is the winning result are predetermined. It is possible to execute the notification indicating that the setting-related process is being executed.

Features αN5. The first predetermined operation means is a pattern display means (first special figure display section 425, second special figure display section 426) for variably displaying the pattern,
The second predetermined operation means is a variable ball entering means (special electric prize winning device 416) provided to be switchable between an open state and a closed state,
The first predetermined operation control means brings the pattern display means into a state corresponding to the first period by performing variable display of the pattern in the first period,
The gaming machine according to feature αN4, wherein the second predetermined operation control means sets the variable ball entering means in a state corresponding to the second period by setting the open state in the second period. ..

According to the characteristic αN5, the variable ball entrance means is opened in the situation where the variable display of the picture is being performed in the picture display means in the situation where the predetermined setting-related processing is being executed. This allows the manager of the game hall to clearly recognize that the predetermined setting-related processing is being executed.

Features αN6. The predetermined setting-related processing is processing for enabling setting of the setting value to be used by the setting means, or processing for notifying the current setting value. The gaming machine according to any one of the features αN1 to αN5.

According to the characteristic αN6, in order to notify the current setting value or the situation in which the process enabling the setting of the setting value to be used is being executed while exhibiting the excellent effect as described above. It is possible for the manager of the game hall to recognize that the process is being executed.

In addition, with respect to the configurations of the features αN1 to αN6, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αO group>
Features αO1. Predetermined display means (first special figure display unit 425, second special figure display unit 426) for performing a predetermined display in the situation where the game is being executed,
Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (function of executing the process of step SB311 in the main CPU 63),
In a situation where a predetermined setting-related process (setting value update process, setting confirmation process) relating to the set value is being executed, the predetermined display means is used to notify that the predetermined setting-related process is being executed. Execution notification control means (a function of executing the processes of steps SE304 and SE308 in the main CPU 63 in the 64th embodiment, and a function of executing steps SE604 and SE607 in the main CPU 63 in the 65th embodiment). A function of executing the process, a function of executing the processes of steps SE704 and SE707 in the main CPU 63 in the 66th embodiment, a function of executing the processes of steps SE904 and SE907 in the main CPU 63 in the 67th embodiment, In the sixty-eighth embodiment, a function of controlling display of the 15R display unit 481 in the main CPU 63),
A gaming machine characterized by being equipped with.

According to the characteristic αO1, since the setting value to be used is set from the setting values of the plurality of stages corresponding to the advantage of the player, the player can use the more advantageous setting value as the usage target. Will be expected. In this case, in a configuration including a predetermined display means for performing a predetermined display in a situation where a game is being executed, the predetermined display means is used in a situation where a predetermined setting-related process relating to a set value is being executed. Then, the notification that the predetermined setting-related processing is being executed is executed. As a result, it becomes possible for the manager of the game hall to recognize that the predetermined setting-related processing is being executed, and at the same time, it is possible to perform this notification using the predetermined display means. ..

Features αO2. The execution notification control means causes the predetermined display means to perform a specific display that does not occur in a situation in which a game is being executed, in a situation in which a predetermined setting-related process relating to the set value is being executed. The gaming machine described in the feature αO1.

According to the characteristic αO2, a specific display that does not occur in a situation in which a game is being executed on a predetermined display means in a situation in which a predetermined setting-related process is being executed is performed. As a result, it is possible to clearly understand from the display contents of the predetermined display means that the predetermined setting-related processing is being executed.

Features αO3. Specific display means (a special display section 429 in the 64th and 65th embodiments, a 6R display section 483 and a small hit display section 484 in the 68th embodiment) for performing a specific display in a situation where a game is being executed. Prepare,
The execution notification control means is configured to notify that the predetermined setting related processing is being executed in the situation where the predetermined setting related processing related to the setting value is being executed, by the predetermined display means and the specific display means. The gaming machine according to the feature αO1 or αO2, which is characterized in that

According to the characteristic αO3, when the notification indicating that the predetermined setting-related processing is being executed is to be illegally performed, both the predetermined display means and the specific display means are illegal. Need to give. Therefore, it becomes possible to make it difficult to carry out an act of illegally giving a notification indicating that a predetermined setting-related process is being executed.

Features αO4. The gaming machine according to feature αO3, wherein the predetermined display means and the specific display means are collected in a predetermined range (special view unit 422) visible from the front of the game machine.

According to the characteristic αO4, in the configuration in which the notification that the predetermined setting-related processing is being executed is executed by using the combination of the display content of the predetermined display means and the display content of the specific display means, It is possible to facilitate the confirmation of the display contents.

Features αO5. The execution notification control means causes the predetermined display means to perform a predetermined correspondence display and the specific display means to perform a specific correspondence display in a situation where a predetermined setting-related process relating to the set value is being executed. Is something that
The predetermined correspondence display on the predetermined display means is a display content that can occur in a situation where a game is being executed,
The specific correspondence display in the specific display means is display content that can occur in a situation where a game is being executed,
The gaming machine according to feature αO3 or αO4, wherein the predetermined correspondence display on the predetermined display means and the specific correspondence display on the specific display means do not occur simultaneously in a situation where a game is being executed.

According to the characteristic αO5, in the situation where the predetermined setting-related processing is executed by using the predetermined correspondence display on the predetermined display means and the specific correspondence display on the specific display means that may occur when the game is being executed. It becomes possible to execute the notification indicating that there is.

Features αO6. A means for executing a transfer lottery for deciding whether or not to transfer the game state to a predetermined game state (a function for executing the processing of step SD803 in the main CPU 63),
Means for controlling the display of the predetermined display means such that the stop result corresponding to the lottery result of the transition lottery is displayed after the variable display of the pattern is started (function of executing the process of step SD706 in the main CPU 63) When,
When the lottery result of the transition lottery is a result corresponding to the transition to the predetermined game state, and the corresponding stop result is displayed on the predetermined display means, the game state is changed to the predetermined game state And a means for shifting the main CPU 63 (function of executing the processing of step SD904 and step SE116 in the main CPU 63),
A means for controlling the display of the specific display means so that a state corresponding display is performed in the predetermined game state (a function for executing the processing of step SD903 and step SE115 in the main CPU 63),
Equipped with
The gaming machine according to feature αO5, wherein the predetermined correspondence display is a variable display of the design and the specific correspondence display is the state correspondence display.

According to the characteristic αO6, in the situation where the predetermined setting related processing is being executed, it is shown that the predetermined display means is in the predetermined game state in the situation where the variable display of the pattern is being performed on the predetermined display means. A status corresponding display is performed. This allows the manager of the game hall to clearly recognize that the predetermined setting-related processing is being executed.

Features αO7. The predetermined setting-related processing is processing for enabling setting of the setting value to be used by the setting means, or processing for notifying the current setting value. The gaming machine according to any one of the features αO1 to αO6.

According to the characteristic αO7, in order to provide the excellent effect as described above, to notify the situation or the current setting value in which the process enabling the setting of the setting value to be used is being executed. It is possible for the manager of the game hall to recognize that the process is being executed.

In addition, with respect to the configurations of the features αO1 to αO7, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αP group>
Features αP1. The first corresponding state in which the first specific operation means (special display unit 429 in the 64th embodiment, special electric prize winning apparatus 416 in the 66th embodiment) is in the first corresponding state in a situation where the game is being executed Executing means (a function of executing the processing of step SD903 and step SE115 in the main CPU 63 in the 64th embodiment, a function of executing the processing of step SD710 to step SD712 in the main CPU 63 in the 66th embodiment);
When the first specific operation means is in the first corresponding state in the game being executed, the second specific operation means (in the 64th embodiment, the special display portion 429 and the second special figure display portion 426, In the sixty-sixth embodiment, the special display unit 429) is set to the second corresponding state (second corresponding state execution means) (in the sixty-fourth embodiment, the main CPU 63 executes the process of step SD706, the sixty-sixth embodiment). In the embodiment, the function of executing the processing of step SD903 and step SE115 in the main CPU 63),
Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (function of executing the process of step SB311 in the main CPU 63),
In a situation where a predetermined setting-related process (setting value updating process, setting confirmation process) relating to the setting value is being executed, the first specific operation means is in the first corresponding state, and the second specific operation means is Specific correspondence control means for making the state different from the second corresponding state (in the sixty-fourth embodiment, a function of executing the processes of step SE304, step SE305, step SE308, and step SE309 in the main CPU 63, the sixty-sixth embodiment). In the embodiment, the function of executing the processing of step SE704, step SE707, step SE802 and step SE816 in the main CPU 63),
A gaming machine characterized by being equipped with.

According to the characteristic αP1, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player can set the more advantageous setting value as the usage target. Will be expected. In this case, in a situation where the game is being executed, when the first specific operation means is in the first corresponding state, the second specific operation means is in the second corresponding state In the situation where the process is being executed, the first specific operation means is in the first corresponding state, whereas the second specific operation means is in a state different from the second corresponding state. As a result, it becomes possible for the manager of the game hall to recognize that the predetermined setting-related processing is being executed, and this notification is sent using the first specific operation means and the second specific operation means. It becomes possible to do it.

Feature αP2. One of the first specific operation means and the second specific operation means is a display means, and the other is a movable means, the gaming machine according to feature αP1.

According to the characteristic αP2, since the notification indicating that the predetermined setting-related processing is being executed is made by the combination of the respective states of the display means and the movable means, the predetermined setting-related processing is executed. It becomes easier to understand that the situation is.

Features αP3. The second specific operation means is a variable ball entering means (special electric prize winning device 416) that can be switched between an open state and a closed state in a predetermined game state,
The second corresponding state is a state in which the second specific operation means is switched between an open state and a closed state,
The first specific operation means is a display means (special display section 429) for performing a display indicating that the predetermined game state is achieved by becoming the first corresponding state in the predetermined game state,
The gaming machine according to feature αP1 or αP2, wherein the specific correspondence control unit maintains the second specific operation unit in the closed state in a situation where the predetermined setting related process is being executed.

According to the characteristic αP3, in the situation where the predetermined setting-related processing is being executed, the second specific operation means is displayed despite the fact that the first specific operation means is displaying that the predetermined game state is in effect. It remains closed. This allows the manager of the game hall to clearly recognize that the predetermined setting-related processing is being executed.

Features αP4. The first specific operation means is a variable ball entering means (special electric prize winning device 416) that can be switched between an open state and a closed state in a predetermined game state,
The first corresponding state is the open state,
The second specific operation means is a display means (special display section 429) for performing a display indicating the predetermined game state by being in the second corresponding state in the predetermined game state. The gaming machine described in the characteristics αP1 or αP2.

According to the characteristic αP4, it is shown that the second specific operation means is in the predetermined game state while the first specific operation means is in the open state in the situation where the predetermined setting related processing is executed. No display. This allows the manager of the game hall to clearly recognize that the predetermined setting-related processing is being executed.

Features αP5. The gaming machine according to feature αP4, wherein the specific correspondence control means sets the second specific operation means to a non-display state in a situation where the predetermined setting related processing is being executed.

According to the characteristic αP5, the display indicating that the second specific operation means is in the predetermined game state in spite of the first specific operation means being in the open state in the situation where the predetermined setting related processing is executed. Not only is it not performed, but it is also hidden. This allows the manager of the game hall to clearly recognize that the predetermined setting-related processing is being executed.

Features αP6. A means for executing a transfer lottery for deciding whether or not to transfer the game state to a predetermined game state (a function for executing the processing of step SD803 in the main CPU 63) is provided,
The second corresponding state execution means controls the display of the second specific operation means so that the stop result corresponding to the lottery result of the transition lottery is displayed after the variable display of the pattern is started,
In the present gaming machine, when the lottery result of the transition lottery is a result corresponding to the transition to the predetermined game state, and the transition stop result which is the stop result corresponding to the result is the second specific operation means. After the display, means for shifting the game state to the predetermined game state (function of executing the processing of step SD904 and step SE116 in the main CPU 63) is provided,
The first corresponding state execution means switches the first specific operation means between an open state and a closed state in the predetermined game state,
The first corresponding state is the open state,
The second corresponding state is a state in which the transition stop result is displayed by the second specific operation means, the gaming machine according to the characteristic αP1 or αP2.

According to the characteristic αP6, in the situation where the predetermined setting-related processing is executed, the transition stop result is not displayed in the second specific operation means even though the first specific operation means is in the open state. This allows the manager of the game hall to clearly recognize that the predetermined setting-related processing is being executed.

Features αP7. The predetermined setting-related processing is processing for enabling setting of the setting value to be used by the setting means, or processing for notifying the current setting value. The gaming machine according to any one of the features αP1 to αP6.

According to the feature αP7, in order to notify the current setting value or the situation in which the process enabling the setting of the setting value to be used is being executed while exhibiting the excellent effect as described above. It is possible for the manager of the game hall to recognize that the process is being executed.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features αP1 to αP7. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αQ group>
Features αQ1. A variable ball entering means (special electric prize winning device 416) provided so that a game ball flowing down in the game area can enter and is switchable between an open state and a closed state,
Update means for updating the updated numerical value information each time an update trigger occurs (function of executing the process of step S8902 in the main CPU 63);
Predetermined acquisition means for acquiring the updated numerical value information when a predetermined acquisition trigger has occurred (in the 64th embodiment, a function of executing the processing of step SD701 for the second special drawing side pending information in the main CPU 63, 69 to 71st embodiment, a function of executing the processing of step SF101 in the main CPU 63),
Predetermined shift determination means for performing a predetermined shift determination for determining whether or not the updated numerical information acquired by the predetermined acquisition means corresponds to numerical information corresponding to a shift to a predetermined game state (open/close execution mode) (In the 64th embodiment, the main CPU 63 has a function of executing the process of step SD803 on the second special drawing side pending information. In the 69th to 71st embodiments, the main CPU 63 has the first special drawing side. A function of executing the processing of step SF304 for the hold information),
Switching control means for switching the variable ball entering means between the open state and the closed state in the predetermined game state (in the sixty-fourth embodiment, a function of executing steps SD710 to SD712 in the main CPU 63, In the 69th to 71st embodiments, a function of executing the processing of steps SF108 to SF110 and step SF208 to step SF210 in the main CPU 63),
Based on the result of the predetermined shift determination being the first winning result (big hit result), the game mode is shifted to the predetermined game state, and the game mode affecting the advantage of the player is set after the end of the predetermined game state. First shifting means that can be changed from before the start of the predetermined game state (in the 64th embodiment, regarding the hold information on the second special figure side in the main CPU 63, step SD805 to step SD807, step SD904, and step SE202 to step SE208) A function of executing processing, in the sixty-seventh to seventy-first embodiments, a function of executing processing of step SF306 to step SF308 and step SF403 for holding information on the first special figure side in the main CPU 63),
Based on the result of the predetermined shift determination being the second winning result (small hit result), the state is shifted to a state where a trigger for shifting to the predetermined game state can be generated, or the predetermined game state is shifted to the predetermined game state. Second transition means for continuing the game mode before the start of the predetermined game state after the end of the game state (in the sixty-fourth embodiment, regarding the hold information on the second special figure side in the main CPU 63, steps SD809 to SD811 and A function of executing the process of step SD915, a function of executing the processes of step SF310, step SF311 and step SF405 with respect to the reservation information on the first special figure side in the main CPU 63 in the 69th to 71st embodiments),
Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (function of executing the process of step SB311 in the main CPU 63),
Equipped with
When the result of the predetermined shift determination is a result of deviation, the shift to the predetermined game state does not occur,
It is determined that the second setting value (for example, “setting 6”) is the first winning result in the predetermined shift determination than the first setting value (for example, “setting 1”) among the setting values of the plurality of stages. In the configuration, the number of the updated numerical information
The second set value is configured such that the number of the update numerical value information that is determined to be the deviation result in the predetermined shift determination is smaller than the first set value by the second specific number.
A game machine characterized in that the second specific number is equal to or larger than the first specific number.

According to the characteristic αQ1, the player is transferred to the predetermined game state in which the variable ball entrance means is in the open state when the result of the first shift or the second prize is reached in the predetermined shift determination, so that the player wins the first win result or the second win result. 2 You will play the game while expecting to win the result. Further, since the state of the game state after that is different depending on whether the first winning result is obtained or the second winning result is determined in the predetermined transition determination, the game state transition mode is diversified. Is possible. In addition, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player can confirm that the more advantageous setting value is to be used. You will expect it.

In this case, a variation in the number of update numerical value information that is determined to be the first winning result in the predetermined transition determination between the first setting value and the second setting value is the deviation result in the predetermined transition determination. It is absorbed by the variation in the number of updated numerical information determined to be. As a result, the probability of being the first winning result in the predetermined transition determination is set between the first setting value and the second setting value while not affecting the probability of the second winning result in the predetermined transition determination. It is possible to change.

Features αQ2. It is determined that the variation of the number of the updated numerical value information that is determined to be the first winning result in the predetermined shift determination in all the setting values of the plurality of stages is the deviation result in the predetermined shift determination. The gaming machine according to feature αQ1, wherein the gaming machine is absorbed by a variation in the number of the updated numerical information.

According to the characteristic αQ2, the probability of being the first winning result in the predetermined transition determination is changed while not affecting the probability of being the second winning result in the predetermined transition determination for all of the setting values in a plurality of stages. Is possible.

Features αQ3. The gaming machine according to the feature αQ1 or αQ2, in which the number of the update numerical value information determined to be the second winning result in the predetermined shift determination is the same for all of the setting values of the plurality of stages ..

According to the characteristic αQ3, it is possible to make constant the probability of being the second winning result in the predetermined shift determination for all of the setting values in a plurality of stages. Further, even if the probability that the second winning result is determined by the predetermined transition determination is constant, the variation of each set value of the probability that the first winning result is determined by the predetermined transition determination is a deviation result. The probability of becoming the first winning result in the predetermined transition determination can be set to the probability corresponding to the set value, because the change is absorbed by the variation.

Features αQ4. Any one of the characteristics αQ1 to αQ3 characterized in that the number of the update numerical value information determined to be the deviation result in the predetermined shift determination is the largest regardless of the setting values of the plurality of stages. Gaming machine described in.

According to the characteristic αQ4, in a configuration in which the number of pieces of update numerical value information determined to be a deviation result in the predetermined shift determination is the largest regardless of each set value, the first winning result is obtained in the predetermined shift determination. The variation of each set value of the number of update numerical information determined to be absorbed by the variation of the number of update numerical information determined to be a deviation result in the predetermined shift determination. As a result, even if the variation in each setting value of the probability of being the first winning result in the predetermined transition determination is absorbed by the variation of the probability of the deviation result in the predetermined transition determination, the predetermined transition determination is performed. With respect to the probability of a deviation result, it is possible to prevent large fluctuations between setting values in a plurality of stages.

Features αQ5. As the game mode, there is a high-probability mode and a low-probability mode in which the probability of being the first winning result in the predetermined shift determination is relatively high or low,
In the situation where the probability that the first winning result is the highest in the predetermined transition determination among the setting values of the plurality of stages is the highest setting value and the game mode is the high probability mode, the predetermined transition determination 2. The gaming machine according to any one of the features αQ1 to αQ4, wherein the number of the updated numerical value information determined to be the deviation result is 0.

According to the characteristic αQ5, it is determined that the predetermined transition determination is the outlier result in the high setting mode in which the probability of being the first winning result is the highest in the predetermined transition determination and the high probability mode. The number of updated numerical information is 0. As a result, in the configuration in which the variation in each set value of the probability of being the first winning result in the predetermined transition determination is absorbed by the variation of the probability of the deviation result in the predetermined transition determination, the predetermined transition determination is performed as described above. It is possible to maximize the probability of being the first winning result in a situation where the probability of being the first winning result is highest.

Features αQ6. As the game mode, there is a high-probability mode and a low-probability mode in which the probability of being the first winning result in the predetermined shift determination is relatively high or low,
In the situation where the probability that the first winning result is the highest in the predetermined transition determination among the setting values of the plurality of stages is the highest setting value and the game mode is the high probability mode, the predetermined transition determination 2. The gaming machine according to any one of the features αQ1 to αQ4, wherein the number of the updated numerical value information determined to be the deviation result is 1 or more.

According to the characteristic αQ6, it is determined that the predetermined transition determination is a deviation result in the high probability mode in which the probability that the first winning result is the highest in the predetermined transition determination is highest. The number of updated numerical value information to be set is one or more. As a result, in the configuration in which the variation in each set value of the probability of being the first winning result in the predetermined transition determination is absorbed by the variation of the probability of the deviation result in the predetermined transition determination, the predetermined transition determination is performed as described above. Thus, even in a situation in which the probability of becoming the first winning result is the highest, it is possible to select the deviating result by the predetermined shift determination.

Features αQ7. A specific acquisition unit (a function of executing the process of step SF201 in the main CPU 63 in the 69th to 70th embodiments) that acquires the updated numerical value information when a specific acquisition trigger occurs;
Specific shift determining means for performing a specific shift determination for determining whether or not the updated numerical value information acquired by the specific acquiring means corresponds to the numerical value information corresponding to the shift to the predetermined gaming state (69th to 69th) In the 70th embodiment, a function of executing the process of step SF304 on the second special drawing side reservation information in the main CPU 63),
Equipped with
The first shift means shifts to the predetermined game state based on the result of the specific shift determination being the first winning result, and sets the game mode after the end of the predetermined game state to the predetermined game state. Can be changed before the start of
The second shifting means shifts to a state where a trigger for shifting to the predetermined gaming state may occur, or shifts to the predetermined gaming state, based on the result of the specific shift determination being the second winning result. After the end of the predetermined game state, the game mode before the start of the predetermined game state is continued,
When the result of the specific transition determination is the result of the deviation, the transition to the predetermined game state does not occur,
The variation due to the difference in the setting value of the number of the update numerical value information determined to be the first winning result in the specific transition determination is determined to be the deviation result in the specific transition determination. The gaming machine according to any one of features αQ1 to αQ6, which is absorbed by a variation in the number of updated numerical information.

According to the characteristic αQ7, the probability of becoming the first winning result is changed between the respective set values while not affecting the probability of becoming the second winning result not only in the predetermined migration judgment but also in the specific migration judgment. It becomes possible.

Features αQ8. The gaming machine according to feature αQ7, wherein all the setting values of the plurality of stages have the same number of the update numerical value information determined to be the second winning result in the specific shift determination.

According to the characteristic αQ8, the probability of being the second winning result can be made constant in all of the setting values of a plurality of stages not only in the predetermined transition determination but also in the specific transition determination. In addition, even if the probability that the second winning result is determined by the specific transition determination is constant as described above, the variation of each set value of the probability that the first winning result is determined by the specific transition determination is a deviation result. The probability of becoming the first winning result in the specific transition determination can be set to the probability according to the set value, because it is absorbed by the variation of the probability.

Features αQ9. The number of the update numerical value information determined to be the deviation result in the specific shift determination is the largest regardless of any of the setting values of the plurality of stages, the game according to the feature αQ7 or αQ8 Machine.

According to the characteristic αQ9, in the configuration in which the number of pieces of update numerical value information that is determined to be a deviation result in the specific shift determination is the largest regardless of each set value, the first winning result is obtained in the specific shift determination. The fluctuation of each set value of the number of updated numerical information determined to be absorbed by the fluctuation of the number of updated numerical information determined to be a deviation result in the specific shift determination. As a result, even if the variation in each setting value of the probability of being the first winning result in the specific transition determination is absorbed by the variation of the probability of being the deviation result in the specific transition determination, the specific transition determination is performed. It is possible to prevent a large change in the probability of a deviation result.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features αQ1 to αQ9. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αR group>
Features αR1. A variable ball entering means (special electric prize winning device 416) provided so that a game ball flowing down in the game area can enter and is switchable between an open state and a closed state,
Update means for updating the updated numerical value information each time an update trigger occurs (function of executing the process of step S8902 in the main CPU 63);
Predetermined acquisition means for acquiring the updated numerical value information when a predetermined acquisition trigger has occurred (in the 64th embodiment, a function of executing the processing of step SD701 for the second special drawing side pending information in the main CPU 63, 69 to 71st embodiment, a function of executing the processing of step SF101 in the main CPU 63),
Predetermined shift determination means for performing a predetermined shift determination for determining whether or not the updated numerical information acquired by the predetermined acquisition means corresponds to numerical information corresponding to a shift to a predetermined game state (open/close execution mode) (In the 64th embodiment, the main CPU 63 has a function of executing the process of step SD803 on the second special drawing side pending information. In the 69th to 71st embodiments, the main CPU 63 has the first special drawing side. A function of executing the processing of step SF304 for the hold information),
Switching control means for switching the variable ball entering means between the open state and the closed state in the predetermined game state (in the sixty-fourth embodiment, a function of executing steps SD710 to SD712 in the main CPU 63, In the 69th to 71st embodiments, a function of executing the processing of steps SF108 to SF110 and step SF208 to step SF210 in the main CPU 63),
Based on the result of the predetermined shift determination being the first winning result (big hit result), first shift means for shifting to the predetermined game state (in the 64th embodiment, on the second special map side in the main CPU 63) With respect to the hold information, the function of executing the processes of step SD805 to step SD807, step SD904, and step SE202 to step SE208. A function of executing the processing of SF308 and step SF403),
Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (function of executing the process of step SB311 in the main CPU 63),
Equipped with
As a result of the predetermined transition determination, there is another winning result other than the deviation result and the first winning result in which the transition to the predetermined gaming state does not occur,
It is determined that the second setting value (for example, “setting 6”) is the first winning result in the predetermined shift determination than the first setting value (for example, “setting 1”) among the setting values of the plurality of stages. The number of the updated numerical information is
The number of the update numerical value information determined in the predetermined shift determination as a predetermined target result (outcome result) different from the first winning result is the highest in each of the first setting value and the second setting value. There are many configurations,
The second set value is configured such that the number of the update numerical value information determined to be the predetermined target result in the predetermined shift determination is smaller than the first set value by a second predetermined number.
A game machine characterized in that the second predetermined number is equal to or larger than the first predetermined number.

According to the characteristic αR1, when the predetermined shift determination results in the first winning result, the variable ball entering means shifts to the predetermined gaming state in which the player is in the open state, so that the player expects the first winning result. A game will be played. In addition, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player can confirm that the more advantageous setting value is to be used. You will expect it.

In this case, in the configuration in which the number of pieces of updated numerical information determined to be the predetermined target result in the predetermined transition determination is the largest regardless of the first setting value and the second setting value, 1 The update numerical value information that is determined to be the predetermined target result in the predetermined transition determination, by the variation between the first setting value and the second setting value of the number of update numerical value information that is determined to be the winning result It is absorbed by the fluctuation of the number of. As a result, even if the variation in each setting value of the probability of being the first winning result in the predetermined transition determination is absorbed by the variation in the probability of being the predetermined target in the predetermined transition determination, the predetermined transition determination Thus, it is possible to prevent a large change in the probability of the predetermined target result. Therefore, while the setting value can be predicted from the probability that the first winning result is selected in the predetermined transition determination, the predetermined target result whose probability changes according to the change in the probability of the first winning result is selected. The probability of being set makes it difficult to predict the set value.

Features αR2. The number of the update numerical value information that is determined to be the predetermined target result in the predetermined transition determination is the largest configuration in any of the setting values of the plurality of stages,
It is determined that the variation in the number of the update numerical value information that is determined to be the first winning result in the predetermined shift determination in all of the setting values of the plurality of stages is the predetermined target result in the predetermined shift determination. The gaming machine according to feature αR1, wherein the gaming machine is absorbed by a variation in the number of the updated numerical information.

According to the feature αR2, the variation of the probability of being the first winning result in the predetermined transition determination is absorbed by the variation of the relatively small probability of the predetermined target result having the highest selection probability in all the setting values of the plurality of stages. It becomes possible.

Features αR3. There is a high-probability mode and a low-probability mode in which the probability of being the first winning result is relatively high or low in the predetermined transition determination.
Even in the situation where the setting value having the highest probability of being the first winning result in the predetermined transition determination among the setting values of the plurality of stages and the high probability mode is set, the predetermined transition determination still remains. The gaming machine according to the characteristic αR1 or αR2, wherein the number of the updated numerical value information determined to be the predetermined target result is the largest.

According to the characteristic αR3, the predetermined target result is determined in the predetermined transition determination even in the high-probability mode in which the probability that the first winning result is the highest in the predetermined transition determination is the highest. The number of pieces of updated numerical information determined to be the largest is the largest. As a result, even if the high probability mode is the highest setting value in which the probability of being the first winning result in the predetermined transition determination is the highest, the probability of being the predetermined target result in the predetermined transition determination With respect to the above, it is possible to absorb the variation in the probability of being the first winning result in the predetermined transition determination by the variation of the probability of being the predetermined target result in the predetermined transition determination, while preventing a large change in the probability. Become.

Features αR4. A specific acquisition unit (a function of executing the process of step SF201 in the main CPU 63 in the 69th to 70th embodiments) that acquires the updated numerical value information when a specific acquisition trigger occurs;
Specific shift determining means for performing a specific shift determination for determining whether or not the updated numerical value information acquired by the specific acquiring means corresponds to the numerical value information corresponding to the shift to the predetermined gaming state (69th to 69th) In the 70th embodiment, a function of executing the process of step SF304 on the second special drawing side reservation information in the main CPU 63),
Equipped with
The first shift means shifts to the predetermined game state based on the result of the specific shift determination being the first winning result,
As a result of the specific transition determination, there is another winning result other than the deviation result and the first winning result in which the transition to the predetermined game state does not occur,
There is a specific target result (missing result) as a lottery result that is not the lottery result with the highest probability of being selected in the specific transition determination in each of the first setting value and the second setting value,
The second setting value is configured such that the number of the update numerical value information determined to be the first winning result in the specific transition determination is larger than the first setting value by the first specific number,
The second set value is configured such that the number of the update numerical value information determined to be the specific target result in the specific transition determination is smaller than the first set value by the second specific number,
The gaming machine according to any one of the features αR1 to αR3, wherein the second specific number is equal to or larger than the first specific number.

According to the feature αR4, the variation in the probability of the specific target result that is not the highest selection probability in the specific transition determination absorbs the variation in the probability of each setting value that is the first winning result in the specific transition determination. Thereby, in the specific transition determination, the player can infer the set value by using each of the selection probability of the first winning result and the selection probability of the specific target result.

Features αR5. The gaming machine according to feature αR4, wherein the specific target result is the predetermined target result.

According to the feature αR5, it is difficult to infer the set value depending on the selection probability of the predetermined target result in the predetermined transition determination, while facilitating the estimation of the set value based on the selection probability of the predetermined target result in the specific transition determination. Is possible.

Features αR6. The specific target result in all of the setting values of the plurality of stages is a configuration in which the probability of being selected in the specific transition determination is not the highest lottery result,
It is determined that the variation of the number of the updated numerical value information that is determined to be the first winning result in the specific transition determination in all of the setting values in the plurality of stages is the specific target result in the specific transition determination. The gaming machine according to the characteristic αR4 or αR5, which is absorbed by a variation in the number of the updated numerical information.

According to the feature αR6, it is possible to absorb the variation in the probability of being the first winning result in the specific transition determination due to the relatively large variation of the specific target result in all of the setting values of the plurality of stages. ..

Features αR7. A specific acquisition unit (a function of executing the process of step SF201 in the main CPU 63 in the seventy-first embodiment) that acquires the updated numerical value information when a specific acquisition trigger occurs;
Specific shift determination means for performing a specific shift determination for determining whether the updated numerical value information acquired by the specific acquisition means corresponds to the numerical value information corresponding to the shift to the predetermined gaming state (71st In the embodiment, the function of executing the processing of step SF304 on the second special drawing side reservation information in the main CPU 63),
Equipped with
The first shift means shifts to the predetermined game state based on the result of the specific shift determination being the first winning result,
As a result of the specific transition determination, there is another winning result other than the deviation result and the first winning result in which the transition to the predetermined game state does not occur,
The number of the update numerical value information determined in the specific shift determination as a specific target result (small hit result) different from the first winning result is in each of the first setting value and the second setting value. The most common configuration,
The second setting value is configured such that the number of the update numerical value information determined to be the first winning result in the specific transition determination is larger than the first setting value by the first specific number,
The second set value is configured such that the number of the update numerical value information determined to be the specific target result in the specific transition determination is smaller than the first set value by the second specific number,
The second specific number is equal to or more than the first specific number,
The gaming machine according to any one of features αR1 to αR3, wherein the predetermined target result and the specific target result are different.

According to the characteristic αR7, even if the lottery result having the highest selection probability is different between the predetermined transition determination and the specific transition determination, the selection probability of the lottery result having the highest selection probability in each of the predetermined transition determination and the specific transition determination By the fluctuation amount of, the fluctuation amount between the setting values of the selection probability of the first winning result is absorbed. As a result, in both the predetermined transition determination and the specific transition determination, the setting value can be estimated from the probability that the first winning result is selected, but the probability changes according to the variation in the probability of the first winning result. It is possible to make it difficult to infer the set value from the probability that different lottery results will be selected.

Features αR8. The number of the update numerical value information that is determined to be the specific target result in the specific transition determination is the largest configuration in any of the setting values of the plurality of stages,
It is determined that the variation in the number of the update numerical value information that is determined to be the first winning result in the specific transition determination in all of the setting values of the plurality of stages is the specific target result in the specific transition determination. The gaming machine according to feature αR7, wherein the gaming machine is absorbed by a variation in the number of the updated numerical information.

According to the characteristic αR8, regardless of whether the predetermined shift determination or the specific shift determination is made, the variation of the relatively small probability of the lottery result having the highest selection probability in all of the setting values of the plurality of stages results in the first winning result. It is possible to absorb fluctuations in probability.

In addition, with respect to the configurations of the features αR1 to αR8, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αS group>
Features αS1. Update means for updating the updated numerical value information each time an update trigger occurs (function of executing the process of step S8902 in the main CPU 63);
A predetermined acquisition unit (a function for executing the process of step SF201 in the main CPU 63 in the 70th embodiment) that acquires the updated numerical value information when a predetermined acquisition trigger occurs.
Predetermined shift determination means for performing a predetermined shift determination for determining whether or not the updated numerical information acquired by the predetermined acquisition means corresponds to numerical information corresponding to a shift to a predetermined game state (open/close execution mode) (In the seventy-seventh embodiment, the main CPU 63 executes the process of step SF304 on the second special figure pending information),
Based on that the result of the predetermined shift determination is the first winning result (a big hit result when the holding information on the second special diagram side in the 70th embodiment is the target of the winning/disabling determination process), the predetermined game A first transition means (a function for executing the processing of step SF306 to step SF308 and step SF403 for the second special drawing side reservation information in the main CPU 63 in the 70th embodiment), which enables the transition to the state;
Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (function of executing the process of step SB311 in the main CPU 63),
Equipped with
When the result of the predetermined shift determination is a result of deviation, the shift to the predetermined game state does not occur,
There is a high-probability mode and a low-probability mode in which the probability of being the first winning result is relatively high or low in the predetermined transition determination.
In the high probability mode, in the predetermined shift determination, the fluctuation amount between the setting values of the plurality of stages of the number of the update numerical value information determined to be the first winning result in the predetermined shift determination is determined by the predetermined shift determination. It is configured to be absorbed by a variation in the number of the updated numerical information determined to be the deviation result,
In the situation where the setting value having the highest probability of being the first winning result in the predetermined transition determination among the setting values of the plurality of stages and the high probability mode is the deviation in the predetermined transition determination In order that the number of the updated numerical information determined to be a result is 1 or more, the setting value having the lowest probability of being the first winning result in the predetermined transition determination among the setting values of the plurality of stages is set. A game machine characterized in that, in a certain situation and in the high probability mode, the number of the update numerical value information determined to be the deviation result in the predetermined shift determination is set.

According to the characteristic αS1, since it is possible to shift to the predetermined game state by the first shift result in the predetermined shift determination, the player can play the game while expecting the first win result. Become. In addition, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player can confirm that the more advantageous setting value is to be used. You will expect it.

In this case, in the high-probability mode, the fluctuation amount between the setting values of the plurality of stages of the number of update numerical value information determined to be the first winning result in the predetermined shift determination is out of the predetermined shift determination. It is absorbed by the variation in the number of updated numerical information determined to be. Then, in the high-probability mode, which is the highest setting value in which the probability of being the first winning result in the predetermined transition determination is the highest, the update numerical value determined to be the outlier result in the predetermined transition determination The number of information is 1 or more. As a result, in the configuration in which the variation in each set value of the probability of being the first winning result in the predetermined transition determination is absorbed by the variation of the probability of the deviation result in the predetermined transition determination, the predetermined transition determination is performed as described above. Thus, even in a situation in which the probability of becoming the first winning result is the highest, it is possible to select the deviating result by the predetermined shift determination.

Features αS2. Based on that the result of the predetermined shift determination is the second winning result (the small hit result when the holding information on the second special figure side in the 70th embodiment is the target of the winning/disallowing determination process) Second shifting means for shifting to a state in which a trigger for shifting to the gaming state can occur, or for shifting to the predetermined gaming state and continuing the game mode before the start of the predetermined gaming state after the end of the predetermined gaming state (second In the 70th embodiment, the main CPU 63 is provided with a function of executing the processing of step SF310, step SF311 and step SF405 with respect to the second special drawing side pending information).
In the high probability mode, the number of the update numerical value information determined to be the second winning result in the predetermined shift determination is the same among the setting values of the plurality of stages. The gaming machine described in αS1.

According to the characteristic αS2, it is possible to make the probability of being the second winning result in a predetermined transition determination constant for all of the setting values in a plurality of stages. Further, even if the probability that the second winning result is determined by the predetermined transition determination is constant, the variation of each set value of the probability that the first winning result is determined by the predetermined transition determination is a deviation result. The probability of becoming the first winning result in the predetermined transition determination can be set to the probability corresponding to the set value, because the change is absorbed by the variation.

Features αS3. Based on that the result of the predetermined shift determination is the second winning result (the small hit result when the holding information on the second special figure side in the 70th embodiment is the target of the winning/disallowing determination process) Second shifting means for shifting to a state in which a trigger for shifting to the gaming state can occur, or for shifting to the predetermined gaming state and continuing the game mode before the start of the predetermined gaming state after the end of the predetermined gaming state (second In the 70th embodiment, the main CPU 63 is provided with a function of executing the processing of step SF310, step SF311 and step SF405 with respect to the second special drawing side pending information).
The number of the update numerical value information determined to be the second winning result in the predetermined transition determination in the high probability mode is the largest in each of the plurality of setting values. The gaming machine described in αS1 or αS2.

According to the characteristic αS3, even if the probability that the second winning result is selected in the predetermined transition determination is the highest in the high probability mode, the probability of being the first winning result in the predetermined transition determination is high. It is possible to select the outlier result in the predetermined transition determination in the highest situation.

In addition, with respect to the configurations of the features αS1 to αS3, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αT group>
Features αT1. A variable ball entering means (special electric prize winning device 416) provided so that a game ball flowing down in the game area can enter and is switchable between an open state and a closed state,
Update means for updating the updated numerical value information each time an update trigger occurs (function of executing the process of step S8902 in the main CPU 63);
A predetermined acquisition unit (a function for executing the process of step SF101 in the main CPU 63 in the 69th to 71st embodiments), which acquires the updated numerical value information when a predetermined acquisition trigger occurs.
Predetermined shift determination means for performing a predetermined shift determination for determining whether or not the updated numerical information acquired by the predetermined acquisition means corresponds to numerical information corresponding to a shift to a predetermined game state (open/close execution mode) (In the 69th to 71st embodiments, the function of executing the process of step SF304 on the pending information on the first special view side in the main CPU 63),
Switching control means for switching the variable ball entering means between the open state and the closed state in the predetermined game state (steps SF108 to SF110 and step SF208 to step in the main CPU 63 in the 69th to 71st embodiments) Function for executing the processing of SF210),
Based on the result of the predetermined shift determination being the first winning result (big hit result), the game mode is shifted to the predetermined game state, and the game mode affecting the advantage of the player is set after the end of the predetermined game state. First shift means that can be changed from before the start of the predetermined game state (in the 69th to 71st embodiments, the processing of steps SF306 to SF308 and step SF403 is executed for the pending information on the first special figure side in the main CPU 63) Function),
Based on the result of the predetermined shift determination being the second winning result (small hit result), the state is shifted to a state where a trigger for shifting to the predetermined game state can be generated, or the predetermined game state is shifted to the predetermined game state. Second transition means for continuing the game mode before the start of the predetermined game state after the end of the game state (in the 69th to 71st embodiments, the holding information on the first special view side in the main CPU 63 is step SF310, A function of executing the processing of step SF311 and step SF405),
Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (function of executing the process of step SB311 in the main CPU 63),
Equipped with
When the result of the predetermined shift determination is a result of deviation, the shift to the predetermined game state does not occur,
As the game mode, there is a high-probability mode and a low-probability mode in which the probability of being the first winning result in the predetermined shift determination is relatively high or low,
In the predetermined shift determination, the probability of being the second winning result is the same regardless of which of the setting value to be used and the game mode set by the setting means. Amusement machine.

According to the characteristic αT1, since the first winning result or the second winning result is determined in the predetermined shift determination, the variable ball entering means is moved to the predetermined gaming state in which the player is in the open state, so that the player wins the first winning result or the second winning result. 2 You will play the game while expecting to win the result. Further, since the state of the game state after that is different depending on whether the first winning result is obtained or the second winning result is determined in the predetermined transition determination, the game state transition mode is diversified. Is possible. In addition, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player can confirm that the more advantageous setting value is to be used. You will expect it.

In this case, the probability of being the second winning result in the predetermined shift determination is the same regardless of the set value and the game mode. This makes it possible to prevent the player from guessing both the set value and the game mode from the probability of being the second winning result.

Features αT2. A specific acquisition unit (a function of executing the process of step SF201 in the main CPU 63 in the 69th to 70th embodiments) that acquires the updated numerical value information when a specific acquisition trigger occurs;
Specific shift determining means for performing a specific shift determination for determining whether or not the updated numerical value information acquired by the specific acquiring means corresponds to the numerical value information corresponding to the shift to the predetermined gaming state (69th to 69th) In the 70th embodiment, a function of executing the process of step SF304 on the second special drawing side reservation information in the main CPU 63),
Equipped with
The first shift means shifts to the predetermined game state based on the result of the specific shift determination being the first winning result, and sets the game mode after the end of the predetermined game state to the predetermined game state. Can be changed before the start of
The second shifting means shifts to a state where a trigger for shifting to the predetermined gaming state may occur, or shifts to the predetermined gaming state, based on the result of the specific shift determination being the second winning result. After the end of the predetermined game state, the game mode before the start of the predetermined game state is continued,
When the result of the specific transition determination is the result of the deviation, the transition to the predetermined game state does not occur,
In the specific shift determination, the probability of being the second winning result is the same regardless of which of the setting value to be used and the game mode set by the setting means. The gaming machine described in the feature αT1.

According to the characteristic αT2, the probability of being the second winning result is the same not only in the predetermined transition determination but also in the specific transition determination, regardless of the set value and the game mode. This makes it possible to prevent the player from inferring both the set value and the game mode from the probability of being the second winning result in either the predetermined shift determination or the specific shift determination.

Features αT3. The gaming machine according to feature αT2, wherein a probability of being the second winning result in the predetermined shift determination is different from a probability of being the second winning result in the specific shift determination.

According to the characteristic αT3, the probability that the second winning result is obtained not only in the predetermined moving judgment but also in the specific moving judgment is the same in both the set value and the game mode, and the second winning result is obtained. It is possible to create a situation in which the probability that

Features αT4. A specific acquisition unit (a function of executing the process of step SF201 in the main CPU 63 in the 69th to 71st embodiments), which acquires the updated numerical value information when a specific acquisition trigger occurs.
Specific shift determining means for performing a specific shift determination for determining whether or not the updated numerical value information acquired by the specific acquiring means corresponds to the numerical value information corresponding to the shift to the predetermined gaming state (69th to 69th) In the seventy-first embodiment, a function of executing the processing of step SF304 with respect to the second special drawing side reservation information in the main CPU 63),
Equipped with
The first shift means shifts to the predetermined game state based on the result of the specific shift determination being the first winning result, and sets the game mode after the end of the predetermined game state to the predetermined game state. Can be changed before the start of
The second shifting means shifts to a state where a trigger for shifting to the predetermined gaming state may occur, or shifts to the predetermined gaming state, based on the result of the specific shift determination being the second winning result. After the end of the predetermined game state, the game mode before the start of the predetermined game state is continued,
When the result of the specific transition determination is the result of the deviation, the transition to the predetermined game state does not occur,
The gaming machine according to feature αT1, wherein the probability of being the second winning result in the predetermined transition determination is different from the probability of being the second winning result in the specific transition determination.

According to the feature αT4, it is possible to cause a situation in which the probability of becoming the second winning result fluctuates.

For the configurations of the features αT1 to αT4, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the inventions related to the characteristic αM group, the characteristic αN group, the characteristic αO group, the characteristic αP group, the characteristic αQ group, the characteristic αR group, the characteristic αS group, and the characteristic αT group, the following problems are solved. It is possible to solve.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as exemplified above, it is necessary to make the configuration relating to the set value that determines the advantage of the gaming machine suitable, and there is still room for improvement in this respect.

<Characteristic αU group>
Features αU1. A specific storage unit (main RAM 65 in the 72nd embodiment) that has a plurality of storage areas associated with addresses and stores information;
Addressing means (step SF801, step SF803, step SF807, step SG101, step SG103, step SG107, step SG201, step SG201, step SG201, step SG201, step SG201 of the main CPU 63 in the 72nd embodiment) for designating a predetermined address in the specific storage means. (Function to execute the processing of SG204 and step SG208),
Specific processing executing means for executing the specific processing on the storage area corresponding to the target address specified by the address specifying means (processing of step SF802, step SG102 and step SG202 of the main CPU 63 in the seventy-second embodiment). Function to execute)
Equipped with
The addressing means is
Address updating means for updating the target address to an address in the next order with respect to the address which is the current target address when the execution of the specific processing by the specific processing executing means is completed (72nd embodiment) Function of executing the process of step SF901 of the main CPU 63 in FIG.
The target address after being updated by the address updating unit is a specific address (hexadecimal number "0100" for the specific control work area 221, and hexadecimal number "0200" for the specific control stack area 222). If the work area 223 for non-specific control is "0300" in hexadecimal, and the stack area 224 for non-specific control is "0400" in hexadecimal, the predetermined first information is the predetermined first information. Information setting means (function of executing the process of step SF903 of the main CPU 63 in the 72nd embodiment) to be set in the storage area (carry flag 516),
Equipped with
A game machine characterized in that the specific processing execution means ends the execution of the specific processing when the predetermined first information is set in the predetermined first information storage area.

According to the characteristic αU1, the target address is sequentially updated, and the storage area corresponding to the updated target address becomes the target of execution of the specific process. Thereby, it becomes possible to sequentially carry out the specific processing on a plurality of storage areas in the specific storage means. In this case, when the updated target address is the specific address, the predetermined first information is set, and when the predetermined first information is set, the execution of the specific process is ended. As a result, when specifying whether or not the execution of the specifying process has been completed for all of the storage areas to be executed, it is only necessary to specify whether or not the predetermined first information is set. It is possible to reduce the processing load for performing. Therefore, it is possible to preferably handle the information stored in the specific storage means.

Features αU2. The address is set as multi-bit data,
The address update means updates the target address by updating the update numerical value for the target address,
The information setting unit changes the value of the reference bit (upper byte 515a) in the data of the plurality of bits when the update numerical value is updated for the target address, and thus the predetermined first information. The gaming machine according to feature αU1, wherein the predetermined first information is set in a storage area.

According to the characteristic αU2, the predetermined first information is set when the value of the reference bit is changed by updating the target address. This makes it possible to simplify the processing configuration for setting the predetermined first information.

Features αU3. The address is set as multi-bit data,
The address updating means updates the target address by adding a numerical value for update to the target address,
The information setting means changes the value of a reference bit (upper byte 515a) different from the least significant bit in the plurality of bits of data when the updating numerical value is added to the target address. 2. The gaming machine according to feature αU1 or αU2, wherein the predetermined first information is set in the predetermined first information storage area.

According to the characteristic αU3, the predetermined first information is set when the carry to the reference bit occurs due to the addition of the updating numerical value to the target address. This makes it possible to simplify the processing configuration for setting the predetermined first information.

Features αU4. There are multiple specific addresses,
In each of the plurality of specific addresses, the value of the reference bit is changed when the updating numerical value is updated for the target address in the situation where the immediately preceding address is set as the target address. The gaming machine according to feature αU2 or αU3, which is an address that is set.

According to the characteristic αU4, in a configuration in which a plurality of specific addresses exist, the target address is updated in a situation where the previous address is set as the target address for any of the specific addresses. The value is changed. Then, the predetermined first information is set by changing the value of the reference bit. This makes it possible to set the predetermined first information at the same trigger even in the configuration in which a plurality of specific addresses exist. Therefore, it is possible to reduce the processing load for identifying the termination trigger of the identification processing.

Features αU5. An address information storage area (address counter 515) configured by a plurality of bytes, in which address information of the target address is set,
The address updating means,
First updating means for updating the target address by updating the updating numerical value for the first byte (lower byte 515b) in the address information storage area (step SF901 of the main CPU 63 in the 72nd embodiment). Function that executes the process of
The second byte in the address information storage area when the numeric value information of the first byte is changed from one of the minimum value and the maximum value to the other by updating the update numerical value for the first byte Second updating means for updating (upper byte 515a) (function of executing the process of step SF905 of the main CPU 63 in the 72nd embodiment);
Equipped with
The specific address is updated in the second byte by changing the numerical value information in the first byte from one of the minimum value and the maximum value to the other by updating the update numerical value in the first byte. Is the resulting address,
The information setting unit updates the first byte by updating the update numerical value so that the numerical value of the first byte is changed from one of the minimum value and the maximum value to the other predetermined value. The predetermined first information is set in one information storage area,
The second updating means stores the second byte when the predetermined first information is set in the predetermined first information storage area when the update numerical value is updated for the first byte. The gaming machine according to any one of the features αU1 to αU4, which is for updating.

When the numeric value information for the first byte is changed from one of the minimum value and the maximum value to the other by updating the update numerical value for the first byte, it is necessary to update the second byte. In this case, when the numerical information of the first byte is changed from one of the minimum value and the maximum value to the other, the predetermined first information is set, and therefore it is specified whether or not the predetermined first information is set. This makes it possible to specify whether or not the second byte needs to be updated. In this case, according to the characteristic αU5, by specifying whether or not the predetermined first information is set, it is specified whether or not the execution of the specifying process is completed for all the storage areas to be executed. It becomes possible to do. Thereby, by using the configuration for identifying whether or not the second byte needs to be updated, it is possible to identify whether or not the specific processing has been completed for all the storage areas to be executed. It becomes possible to do.

Features αU6. The specific processing execution means executes the specific processing for the storage area included in a specific range of addresses in the specific storage means when a specific execution trigger occurs,
In the address in the specific range, the last address in the execution order of the specific processing becomes the specific address, or the address in the order immediately before the specific address (if the work area 221 for specific control is used, Hexadecimal number "00FF", hexadecimal number "01FF" for stack area 222 for specific control, hexadecimal "02FF" for work area 223 for non-specific control, stack area 224 for non-specific control If so, the address of the specific range is set so as to be a hexadecimal number "03FF"), the gaming machine according to any one of features αU1 to αU5.

According to the feature αU6, it is possible to specify whether or not the execution of the specific process for the storage area included in the address of the specific range is completed by specifying whether or not the predetermined first information is set. .. As a result, it becomes easy to specify whether or not the execution of the specifying process for the storage area included in the address of the specified range has been completed.

Features αU7. The gaming machine according to feature αU6, characterized in that an unused storage area exists in the storage area corresponding to an address in the order before the address of the specific range in the specific storage means.

According to the characteristic αU7, the storage area included in the address of the specific range in the specific storage means is set so that it becomes easy to specify whether or not the execution of the specific processing for the storage area included in the address of the specific range is completed. It becomes possible to do.

Features αU8. As the addresses of the specific range, there are a first specific range address (for example, an address range of the stack area 222 for specific control) and a second specific range address (for example, an address range of the stack area 224 for non-specific control). Exists,
The specific processing execution means executes the specific processing on the storage area included in the address of the first specific range in the specific storage means when a first specific execution trigger is generated, and a second specific execution trigger is generated. When the above occurs, the specific processing is performed on the storage area included in the address of the second specific range in the specific storage means.
As the specific address, at least a first specific address corresponding to the address of the first specific range and a second specific address corresponding to the address of the second specific range are present,
In the address of the first specific range, the last address in the execution order of the specific processing becomes the first specific address, or the address immediately before the first specific address, The address of the first specific range is set,
In the address of the second specific range, the last address in the execution order of the specific processing becomes the second specific address, or the address in the order immediately before the second specific address, The gaming machine according to feature αU6 or αU7, wherein an address of the second specific range is set.

According to the feature αU8, it is possible to specify whether or not the execution of the specific process for the storage area included in the first specific range address is completed, and to perform the specific process for the specific storage area included in the second specific range address. In any case of specifying whether or not the execution is completed, it may be specified whether or not the predetermined first information is set. This makes it possible to reduce the processing load for identifying whether or not the execution of the identifying process has been completed.

Features αU9. The gaming machine according to any one of features αU1 to αU8, wherein a plurality of types of the specific processing are present.

According to the feature αU9, it is possible to specify the termination trigger by specifying whether or not the predetermined first information is set regardless of which of the plurality of types of specifying processing is being executed.

Features αU10. The gaming machine according to any one of features αU1 to αU9, wherein the specific process is a process for clearing information in the storage area corresponding to the target address.

According to the feature αU10, it is possible to reduce the processing load for specifying the termination trigger of the process of clearing the information in the storage area of the specific storage unit.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features αU1 to αU10. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, and features βA1 to βA. 4. Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the characteristic αU group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as exemplified above, there is a demand for a configuration capable of suitably executing the processing for the specific storage means for storing information, and there is still room for improvement in this respect.

<Characteristic αV group>
Features αV1. A numerical information storage area (address counter 515) configured by a plurality of bytes and storing numerical information,
First updating means for updating the numerical information by updating the numerical value for update in the first byte (lower byte 515b) in the numerical information storage area (step SF901 of the main CPU 63 in the 72nd embodiment). Function that executes the processing of
When the numerical value information for the first byte is changed from one of the minimum value and the maximum value to the other by updating the update numerical value for the first byte, a predetermined first information storage area (carry An information setting means (a function of executing the processing of step SF903 of the main CPU 63 in the 72nd embodiment) for setting the predetermined first information in the flag 516);
If the predetermined first information is set in the predetermined first information storage area when the update numerical value is updated for the first byte, the second byte (upper byte) in the numerical information storage area is set. 515a) second updating means (a function of executing the process of step SF905 of the main CPU 63 in the 72nd embodiment);
Special process executing means for executing a special process based on the setting of the predetermined first information in the predetermined first information storage area (step SG805 to step SG810 of the main CPU 63 in the 72nd embodiment, step SF105 to step SF105). A function of executing the processing of step SF107 and step SF206 to step SF208),
A gaming machine characterized by being equipped with.

If the numerical information for the first byte is changed from one of the minimum value and the maximum value to the other by updating the update numerical value for the first byte, it is necessary to update the second byte. In this case, when the numerical information of the first byte is changed from one of the minimum value and the maximum value to the other, the predetermined first information is set, and therefore it is specified whether or not the predetermined first information is set. This makes it possible to specify whether or not the second byte needs to be updated. In this case, according to the feature αV1, it is possible to specify whether or not the special process needs to be executed by specifying whether or not the predetermined first information is set. This makes it possible to identify the trigger for executing the special process by using the configuration for identifying the trigger for updating the second-byte numerical information. Therefore, it is possible to reduce the processing load for specifying the trigger for executing the special processing.

Features αV2. When the second byte is updated by setting the predetermined first information in the predetermined first information storage area when the update numerical value is updated for the first byte The first situation (the situation that targets the work area 221 for the specific control and the stack area 222 for the specific control) and the second situation (the work area 223 for the non-specific control and the non (A situation in which the stack area 224 for specific control is targeted) exists,
The special processing executing means may execute the special processing based on the setting of the predetermined first information in the predetermined first information storage area in any of the first situation and the second situation. The gaming machine described in Characteristic αV1.

According to the characteristic αV2, the special process is executed based on the setting of the predetermined first information in any of the first situation and the second situation in which the numerical information of the second byte after update is different. It is possible to reduce the processing load for executing the special processing in each of the first situation and the second situation.

Features αV3. A specific storage unit (main RAM 65 in the 72nd embodiment) which has a plurality of storage areas associated with addresses and stores information,
The numerical information stored in the numerical information storage area is information of a target address,
The gaming machine executes a specific process execution means (a process of step SF802, step SG102 and step SG202 of the main CPU 63 in the 72nd embodiment) in which the specific area is to be executed in the storage area corresponding to the target address. (A) The gaming machine according to the feature αV1 or αV2.

According to the feature αV3, when the special process is executed in association with the update of the target address, it is possible to reduce the processing load for executing the special process.

Features αV4. The game according to the feature αV3, wherein the special process executing means ends the execution of the specific process as the special process when the predetermined first information is set in the predetermined first information storage area. Machine.

According to the feature αV4, by specifying whether or not the predetermined first information is set, it is possible to specify whether or not the execution of the specifying process has been completed for all of the storage areas to be executed. It will be possible. Thereby, by using the configuration for identifying whether or not the second byte needs to be updated, it is possible to identify whether or not the specific processing has been completed for all the storage areas to be executed. It becomes possible to do.

Features αV5. The gaming machine according to feature αV4, wherein a plurality of types of the specific processing are present.

According to the feature αV5, it is possible to specify the termination trigger by specifying whether or not the predetermined first information is set, regardless of which of the plurality of types of specifying processing is being executed.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features αV1 to αV5. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the characteristic αV group, it is possible to solve the following problems.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as exemplified above, there is a demand for a configuration capable of suitably executing the processing in the control means, and there is still room for improvement in this respect.

<Characteristic αW group>
Features αW1. A predetermined operation means (movable body 512),
A predetermined operation control means (sound light side CPU 353) for controlling the operation of the predetermined operation means,
Initial operation control means for causing the predetermined operation means to perform an initial operation when supply of operating power is started (function of executing the processing of step SG311 of the sound-light side CPU 353 in the 72nd embodiment, 73rd embodiment). Function for executing the processing of step SG412 of the sound-light side CPU 353 in FIG.
Delaying means for delaying the start timing of the initial operation (function of executing step SG310 of the sound-light side CPU 353 in the 72nd embodiment, executing step SG411 of the sound-light side CPU 353 in the 73rd embodiment. Function),
A gaming machine characterized by being equipped with.

According to the characteristic αW1, since the predetermined operation means performs the initial operation when the supply of the operation power is started, it is necessary to confirm whether or not the predetermined operation means operates normally when the supply of the operation power is started. Is possible. In this case, since the start timing of the initial operation in the predetermined operation means is delayed, it is not necessary to confirm the initial operation immediately after the supply of the operating power is started, and the initial operation can be confirmed with a margin. Will be possible.

Features αW2. Specific operation means (first to fourth notification display devices 201 to 204),
A specific operation control means (main CPU 63) for controlling the operation of the specific operation means,
A means for causing the specific operation means to perform an initial operation when the supply of operating power is started (a function for executing the process of step SF524 of the main CPU 63 in the 72nd embodiment and a function for executing the second timer interrupt process). )When,
Equipped with
One of the specific operation means and the predetermined operation means is provided so as to be visible by exposing the back side of the gaming machine,
The other one of the specific operation means and the predetermined operation means is provided so as to be visible from the front side of the game machine.

According to the characteristic αW2, since the specific operation means performs the initial operation when the supply of the operation power is started, it is necessary to confirm whether or not the specific operation means operates normally when the supply of the operation power is started. Is possible. Further, one of the specific operation means and the predetermined operation means becomes visible by exposing the back side of the gaming machine, while the other becomes visible from the front side of the game machine, so the specific operation means and the predetermined operation means. In order to confirm the initial operation of each of the operating means, it is necessary to visually check the back side and the front side of the gaming machine. In this case, the configuration of the characteristic αW1 is provided, and the start timing of the initial operation in the predetermined operation means is delayed. This makes it possible to confirm the initial operation in the predetermined operation means after confirming the initial operation in the specific operation means, and it is possible to preferably confirm each initial operation.

Features αW3. Specific operation means (first to fourth notification display devices 201 to 204) provided so as to be visible by exposing the back side of the gaming machine,
A specific operation control means (main CPU 63) for controlling the operation of the specific operation means,
A means for causing the specific operation means to perform an initial operation when the supply of operating power is started (a function for executing the process of step SF524 of the main CPU 63 in the 72nd embodiment and a function for executing the second timer interrupt process). )When,
Equipped with
The gaming machine according to feature αW1, wherein the predetermined operation means is provided so as to be visible from the front side of the gaming machine.

According to the characteristic αW3, since the specific operation means performs the initial operation when the supply of the operation power is started, it is necessary to confirm whether or not the specific operation means operates normally when the supply of the operation power is started. Is possible. Further, the specific operation means becomes visible by exposing the back side of the gaming machine, whereas the predetermined operation means becomes visible from the front side of the game machine, so that each of the specific operation means and the predetermined operation means is visible. In order to confirm the initial operation, it is necessary to visually recognize each of the back side and the front side of the gaming machine. In this case, the configuration of the characteristic αW1 is provided, and the start timing of the initial operation in the predetermined operation means is delayed. Thus, after exposing the back side of the gaming machine and confirming the initial operation in the specific operation means, it is possible to return to the normal state in which the front side of the gaming machine is visible and confirm the initial operation in the predetermined operation means. This makes it possible to suitably confirm each initial operation.

Features αW4. The game machine according to any one of the features αW1 to αW3, wherein the delay unit sets a waiting period for delaying the start timing of the initial operation.

According to the characteristic αW4, since the initial operation of the predetermined operation means is delayed by measuring the standby period, it is possible to simplify the processing configuration for delaying the initial operation of the predetermined operation means.

Features αW5. Equipped with a progress control means (main CPU 63) for controlling the progress of the game,
The predetermined operation control means controls the operation of the predetermined operation means based on the instruction information transmitted from the progress control means,
The delay means is provided with start reference information (in the 72nd embodiment, a normal return command, a clear return command, a check return command and an update return) from the progress control means after the supply of the operating power is started. The game machine according to the feature αW4, wherein the standby period is set when a command, a return command at the time of clearing, a return command at the time of confirmation, and a return command at the time of update) is received.

According to the characteristic αW5, the waiting period is measured with reference to the timing at which the start reference information transmitted from the progress control means is received. As a result, it becomes possible to delay the initial operation of the predetermined operation means on the basis of the progress of the control in the advance control means.

Features αW6. The progress control means executes processing at the start of supply of operating power (steps SF501 to SF523 of the main CPU 63 in the seventy-second embodiment) when the supply of operating power is started. Is for transmitting the start reference information of different types according to the execution contents of the process at the time of starting the supply of the operating power,
The gaming machine according to feature αW5, wherein the delay unit sets the waiting period regardless of which type of the start reference information is received.

According to the characteristic αW6, the progress control means transmits different types of start reference information depending on the content of execution of the process at the start of supply of the operating power. It is possible to execute control according to the execution contents of the process. In this case, the standby period for delaying the initial operation of the predetermined operation means is set regardless of which type of start reference information is transmitted, so that the progress control means can supply the operation power at the start of operation. It is possible to delay the initial operation of the predetermined operation means irrespective of the execution contents of the processing.

Features αW7. The progress control means executes processing at the start of supply of operating power (steps SF501 to SF523 of the main CPU 63 in the seventy-second embodiment) when the supply of operating power is started. Is for transmitting the start reference information of different types according to the execution contents of the process at the time of starting the supply of the operating power,
The delay unit sets the waiting period when receiving a predetermined type of the start reference information (a return command at the time of clearing, a return command at the time of confirmation, and a return command at the time of updating), and sets the waiting period to other than the predetermined type. The gaming machine according to feature αW5, wherein the standby period is not set when the start reference information (normal return command) is received.

According to the characteristic αW7, since the progress control means transmits different types of start reference information according to the execution contents of the processing at the start of the supply of the operating power, the predetermined operation control means causes the progress control means to start supplying the operating power. It is possible to execute control according to the execution contents of the process. In this case, the waiting period is set when the start reference information of the predetermined type is transmitted, and the standby period is not set when the start reference information of a type other than the predetermined type is transmitted. This makes it possible to cause a situation in which the initial operation of the predetermined operation means is delayed and a situation in which the initial operation of the predetermined operation means is not delayed depending on the content of execution of the process at the start of supply of the operating power in the progress control means.

Features αW8. The progress control means executes processing at the start of supply of operating power (steps SF501 to SF523 of the main CPU 63 in the seventy-second embodiment) when the supply of operating power is started. The gaming machine according to any one of features αW5 to αW7, wherein the start reference information is transmitted when a process at the start of supply of operating power is completed.

According to the characteristic αW8, it is possible to delay the initial operation of the predetermined operation means with reference to the timing when the process at the start of supplying the operation power in the progress control means is completed.

Features αW9. The predetermined operation means is provided so as to be visible from the front side of the gaming machine,
When the delay means delays the start timing of the initial operation when the operation of exposing the back side of the gaming machine is performed when the supply of the operation power is started, and the supply of the operation power is started In the gaming machine according to any one of the features αW1 to αW8, the start timing of the initial operation is not delayed when an operation of exposing the back side of the gaming machine is not performed.

According to the characteristic αW9, when the operation of exposing the back side of the gaming machine is performed when the supply of the operating power is started, the start timing of the initial operation of the predetermined operation means is delayed, and thus In such a situation, it is possible to confirm the initial operation of the predetermined operation means after returning to the normal state in which the front side of the gaming machine is visible. On the other hand, if the operation of exposing the rear side of the gaming machine is not performed when the supply of the operating power is started, the start timing of the initial operation of the predetermined operation means is not delayed. Immediately after the supply of the operating power is started, it is possible to confirm the initial operation of the predetermined operating means.

In addition, with respect to the configurations of the features αW1 to αW9, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the characteristic αW group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as exemplified above, it is necessary to suitably confirm whether or not the predetermined operation means normally operates, and there is still room for improvement in this respect.

<Characteristic αX group>
Features αX1. A progress control means (main CPU 63) for controlling the progress of the game,
A predetermined operation means (movable body 512),
Predetermined operation control means (sound-light side CPU 353) for controlling the operation of the predetermined operation means based on the instruction information transmitted from the progress control means;
Equipped with
The progress control means,
When the supply of the operating power is started, the means (the main CPU 63 of the 72nd embodiment) which executes the processing (steps SF501 to SF523 of the main CPU 63 in the 72nd embodiment) at the start of the supply of the operating power A function of executing the processing of step SF501 to step SF523),
When the process at the time of starting the supply of the operating power is executed, the start reference information (in the 72nd embodiment, the normal return command, the clear return command, the confirmation return command and the update return command, the 73rd return command). In the embodiment, the start transmission means (step SF514, step SF519, step SF607 of the main CPU 63 in the 72nd embodiment) for transmitting the normal return command, the clear return command, the confirmation return command, and the update return command. And a function of executing the processing of step SF714),
Equipped with
The predetermined operation control means causes the predetermined operation means to perform a predetermined operation (initial operation) after receiving the start reference information.

According to the characteristic αX1, the predetermined operation means performs the predetermined operation after the predetermined operation control means receives the start reference information transmitted when the process for starting the supply of the operation power is executed by the progress control means. Thus, it becomes possible for the predetermined operation means to perform the predetermined operation after the process at the start of supplying the operating power is executed by the progress control means.

Feature αX2. The start transmission means is for transmitting the different types of start reference information according to the execution contents of the process at the time of starting the supply of the operating power,
The gaming machine according to feature αX1, wherein the predetermined operation control means causes the predetermined operation means to perform the predetermined operation regardless of which type of the start reference information is received.

According to the characteristic αX2, the predetermined operation means performs the predetermined operation regardless of which type of start reference information is transmitted, so that the progress control means determines the execution content of the process at the start of the supply of the operation power. It is possible to perform the predetermined operation by the predetermined operation means regardless of the above.

Features αX3. The start transmission means is for transmitting the different types of start reference information according to the execution contents of the process at the time of starting the supply of the operating power,
The predetermined operation control means receives the start reference information of a predetermined type (a return command at clear, a return command at confirmation, and a return command at update) and the start reference information other than the predetermined type ( The gaming machine according to the feature αX1 or αX2, wherein the control content of the predetermined operation means is different when a normal return command) is received.

According to the characteristic αX3, since the progress control means transmits different types of start reference information depending on the content of execution of the process at the start of supply of the operating power, the predetermined operation control means causes the progress control means to start supplying the operating power. It is possible to execute control according to the execution contents of the process. In this case, the control content of the predetermined operation means differs between the case where the start reference information of the predetermined type is transmitted and the case where the start reference information other than the predetermined type is transmitted. This makes it possible to change the execution mode of the predetermined operation of the predetermined operation means according to the execution content of the process at the start of supply of the operating power in the progress control means.

Features αX4. The gaming machine according to any one of features αX1 to αX3, wherein the start transmitting unit transmits the start reference information when a process at the start of supplying the operating power is completed.

According to the feature αX4, it is possible to cause the predetermined operation means to perform the predetermined operation with reference to the timing when the process at the start of supplying the operation power in the progress control means is completed.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features αX1 to αX4. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the characteristic αX group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as exemplified above, it is necessary to suitably perform control for causing the predetermined operation means to perform the predetermined operation, and there is still room for improvement in this respect.

<Characteristic αY group>
Features αY1. Specific information storage means having a setting correspondence storage area (setting reference area 341) for storing setting correspondence information corresponding to the setting value set as a target to be used from among the setting values of a plurality of stages corresponding to the player's advantage (Main side RAM65),
Means for executing a profit giving process in a mode corresponding to the setting correspondence information (a function of the main CPU 63 for executing the processes of steps S503 and S504);
Setting-related executing means for executing a predetermined setting-related process relating to the set value (function of executing the processes of steps SG701 to SG712 of the main CPU 63 in the seventy-fourth embodiment);
When the predetermined setting-related processing is executed, a predetermined storage area (a work area 221 for specific control and a stack area 222 for specific control) different from the setting corresponding storage area in the specific information storage means is initialized. Initialization executing means for executing initialization processing for initialization (function of executing the processing of steps SG801 to SG807 of the main CPU 63 in the seventy-fourth embodiment);
A gaming machine characterized by being equipped with.

According to the characteristic αY1, the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, so that the player sets the more advantageous setting value as the usage target. Will be expected. In this case, when the predetermined setting-related processing is executed, the predetermined storage area in the specific information storage means is initialized, and when the predetermined setting-related processing is executed, the predetermined storage area is It is possible to start the game in the initialized condition. Further, even when the predetermined storage area is initialized in this way, the setting-corresponding storage area is excluded from the initialization target, so that the predetermined setting-related processing is performed while not changing the setting value. When is executed, it becomes possible to start the game in a situation where a predetermined storage area is initialized.

Features αY2. Specific related notification executing means for executing a specific related notification process for executing a specific related notification when the predetermined setting related process is executed (step SG808 of the main CPU 63 in step SG808 in the seventy-fourth embodiment). The game machine according to feature αY1 having a function of executing processing).

According to the feature αY2, the specific related notification is executed when the predetermined setting related process is executed in the configuration in which the predetermined storage area is initialized when the predetermined setting related process is executed. By confirming that the specific related notification is being executed, the manager of the game hall can recognize that the predetermined setting related processing has been executed and the predetermined storage area has been initialized.

Features αY3. The game according to feature αY2, wherein the specific related notification is executed so that the specific related notification can be confirmed without requiring an opening operation of a gaming machine front body (game machine main body 12). Machine.

According to the feature αY3, since the specific related notification is executed so that it can be confirmed without requiring the opening operation of the gaming machine front body, the manager of the gaming hall has executed the predetermined setting related processing. Also, it becomes easy to understand that the predetermined storage area has been initialized.

Features αY4. The gaming machine according to feature αY2 or αY3, wherein the specific related notification is executed until a specific related period elapses after the predetermined setting related process is executed.

According to the feature αY4, since the specific related notification is executed until the specific related period elapses after the predetermined setting related processing is executed, the manager of the gaming hall understands that the specific related notification is executed. It will be easier.

Features αY5. The gaming machine according to any one of features αY2 to αY4, wherein a process for advancing a game is executed even in a situation where the specific related notification is being executed.

According to the feature αY5, the processing for advancing the game is executed even in the situation where the specific related notification is being executed, so it is possible to execute the specific related notification while not hindering the progress of the game. Becomes

Features αY6. The initialization executing means calls a predetermined aggregation process (RAM clear process in the 74th embodiment) including both the initialization process and the specific related notification process when the predetermined setting related process is executed. Even when the predetermined setting-related processing is not executed, the timing of initialization (when the setting key insertion portion 68a is in the OFF state and the reset button 68c is pressed and operated, the operating power of the main CPU 63 is reduced). The gaming machine according to any one of the features αY2 to αY5, wherein the predetermined aggregation process is called based on the occurrence of (starting supply).

According to the characteristic αY6, the initialization process of the predetermined storage area and the specific related notification process are executed based on the occurrence of the initialization trigger even when the predetermined setting related process is not executed. In this case, regardless of whether the setting related process is executed or the initialization trigger is generated, the initialization process is executed by calling the predetermined aggregation process including both the initialization process and the specific related notification process. Both the processing and the specific related notification processing are executed. This makes it possible to execute both the initialization process and the specific-related notification process in each of the above situations while simplifying the processing configuration.

Features αY7. The setting-related executing means determines that the predetermined event (ON operation of the setting key insertion portion 68a) that occurs when the opening/closing body (game machine main body 12) is in the open state has occurred. It executes setting related processing,
The gaming machine executes a closing correspondence notification executing means for executing the closing correspondence notification based on the opening/closing body being changed from the open state to the closed state (step SG904 of the main CPU 63 in the 74th embodiment). The game machine according to any one of the features Y1 to Y6, which is provided with a function of executing processing.

According to the feature αY7, since the predetermined setting-related processing is executed based on the occurrence of the specific event that occurs in the situation where the opening/closing body is in the open state, the predetermined setting-related processing is executed. Therefore, it is necessary to open the opening/closing body, and it is possible to make it difficult to perform a predetermined setting-related process illegally. Further, since the closure response notification is executed based on that the opening/closing body is changed from the open state to the closed state, the opening/closing body is actually set to the predetermined state after the opening/closing body is opened to illegally execute the predetermined setting-related processing. Even if the opening/closing body is brought into the closed state without causing the setting-related processing of (1) to be illegally executed, the closure response notification is executed after the opening/closing body is brought into the closed state. Therefore, it becomes possible for the manager of the game hall to know the presence or absence of the fraudulent activity.

Features αY8. The setting-related executing means determines that the predetermined event (ON operation of the setting key insertion portion 68a) that occurs when the opening/closing body (game machine main body 12) is in the open state has occurred. It executes setting related processing,
This gaming machine is
Specific related notification executing means for executing a specific related notification process for executing a specific related notification when the predetermined setting related process is executed (step SG808 of the main CPU 63 in step SG808 in the 74th embodiment). Function to execute processing),
Executing a predetermined target notification process for executing a predetermined target notification based on a predetermined target operation being one of an opening operation and a closing operation performed on the opening/closing body Means (function of executing the processing of step SG904 of the main CPU 63 in the seventy-fourth embodiment);
Equipped with
The gaming machine according to any one of the features αY1 to αY7, wherein the specific related notification is set to have a higher execution priority than the predetermined target notification.

According to the feature αY8, the specific related notification is executed when the predetermined setting related process is executed in the configuration in which the predetermined storage area is initialized when the predetermined setting related process is executed. By confirming that the specific related notification is executed, the manager of the game hall can recognize that the predetermined setting related processing has been executed and the predetermined storage area has been initialized. Further, since the predetermined setting-related processing is executed based on the occurrence of the specific event that occurs in the situation where the opening/closing body is in the open state, the opening/closing body is required to execute the predetermined setting-related processing. Is required to be opened, and it is possible to make it difficult to execute a predetermined setting-related process illegally. In addition, since the predetermined target notification is executed based on the predetermined target operation performed on the open/close body, it is possible that the open/close body is opened to illegally execute the predetermined setting-related processing. Also, the predetermined target notification is executed for that. Therefore, it becomes possible for the manager of the game hall to know the presence or absence of the fraudulent activity. Further, since the priority of execution of the specific related notification is set to be higher than that of the predetermined target notification, it is possible to notify whether or not the predetermined target operation is performed on the opening/closing body while the predetermined related notification is performed. It is possible to directly notify that the setting-related processing is being performed.

Features αY9. The predetermined target notification is configured to be executed until a predetermined target related period elapses after the predetermined target operation is performed on the opening/closing body,
The predetermined target notification execution means is a case where the specific target notification is performed with priority over the predetermined target notification, and the predetermined target related period is set after the predetermined target operation is performed on the opening/closing body. The gaming machine according to feature αY8, wherein when the specific related notification ends before the elapse, the predetermined target notification is executed for the remaining period of the predetermined target related period.

According to the feature αY9, in a configuration in which the specific related notification has a higher execution priority than the predetermined target notification, it becomes possible to execute the predetermined target notification after the specific related notification ends. Further, even when the predetermined target notification is executed after the specific related notification ends in this way, the execution period is until the specific related notification ends after the predetermined target operation is performed on the opening/closing body. The remaining period is obtained by subtracting the required period from the predetermined target related period. This makes it possible to prevent the total execution period of these notifications from becoming excessively long when the predetermined target notification is executed after the end of the specific related notification.

Features αY10. The specific related notification is configured to be executed until a specific related period elapses after the predetermined setting related processing is executed,
The gaming machine according to feature αY9, wherein the predetermined target related period is set to be longer than the specific related period.

According to the characteristic αY10, even when the specific related notification is executed with priority over the predetermined target notification, it is possible to ensure the execution period of the predetermined target notification after the end of the specific related notification.

Features αY11. The gaming machine according to any one of features αY1 to αY10, wherein the predetermined setting related process is a process of changing the setting value to be used.

According to the characteristic αY11, when the process of changing the setting value to be used is executed, the predetermined storage area in the specific information storage means is initialized, and thus the setting value to be used is changed. When is executed, it becomes possible to start the game in a situation where a predetermined storage area is initialized. Further, even when the predetermined storage area is initialized in this way, the setting-corresponding storage area is excluded from the initialization target, so that the setting target setting is not changed and the setting target storage area is set. When the process of changing the value is executed, it is possible to start the game in a situation where the predetermined storage area is initialized.

In addition, with respect to the configurations of the features αY1 to αY11, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, and features βA1 to βA. 4. Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the characteristic αY group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as exemplified above, it is necessary to make the configuration relating to the set value that determines the advantage of the gaming machine suitable, and there is still room for improvement in this respect.

<Characteristic αZ group>
Features αZ1. First notification executing means (step SG808 of main CPU 63 in the seventy-fourth embodiment) for executing the first notification based on the occurrence of the first notification trigger (that the setting confirmation process is executed) And the function of executing the processing of step SH107 of the sound-light side CPU 353).
Second notification execution means (second notification execution means for executing the second notification over the second notification period based on the occurrence of the second notification trigger (the opening of the gaming machine main body 12 from the open state) 74, a function of executing the process of step SG904 of the main CPU 63 and a function of executing the process of step SH114 of the sound/light side CPU 353).
Equipped with
The first notification is set to have a higher execution priority than the second notification,
The second notification executing means is a case where the first notification has priority over the second notification and is executed before the second notification period elapses after the second notification trigger occurs. A game machine characterized in that, when one notification is completed, the second notification is executed for the remaining period of the second notification period.

According to the feature αZ1, in a configuration in which the first notification has a higher execution priority than the second notification, it becomes possible to execute the second notification after the first notification ends. In addition, even when the second notification is executed after the first notification is completed in this way, the execution period is the period required until the first notification ends after the second notification trigger occurs. 2 The remaining period is subtracted from the notification period. This makes it possible to prevent the total execution period of these notifications from becoming excessively long when the second notification is executed after the completion of the first notification.

Features αZ2. The first notification is configured to be executed until the first notification period elapses after the first notification trigger has occurred,
The gaming machine according to feature αZ1, wherein the second notification period is set to be longer than the first notification period.

According to the feature αZ2, even when the first notification is executed with priority over the second notification, it is possible to ensure the execution period of the second notification after the end of the first notification.

Features αZ3. Means for executing profit-giving processing in a mode corresponding to the setting value set as the usage target from among the setting values of a plurality of stages corresponding to the player's advantage (the processing of steps S503 and S504 in the main CPU 63 Function to execute)
Based on the occurrence of a specific event (ON operation of the setting key insertion part 68a) that occurs in a situation where the opening/closing body (game machine body 12) is in an open state, a predetermined setting-related process relating to the setting value Setting-related executing means (function for executing the processing of steps SG701 to SG712 of the main CPU 63 in the seventy-fourth embodiment);
Equipped with
When the predetermined setting related process is executed, the first notification trigger occurs,
The gaming machine according to feature αZ1 or αZ2, wherein the second notification trigger is generated based on a predetermined target operation, which is one of an opening operation and a closing operation, being performed on the opening/closing body.

According to the characteristic αZ3, the first notification is executed when the predetermined setting-related processing is executed, so that the manager of the gaming hall confirms that the first notification is executed and thereby performs the predetermined setting. It becomes possible to grasp that the related processing has been executed. Further, since the predetermined setting-related processing is executed based on the occurrence of the specific event that occurs in the situation where the opening/closing body is in the open state, the opening/closing body is required to execute the predetermined setting-related processing. Is required to be opened, and it is possible to make it difficult to execute a predetermined setting-related process illegally. In addition, since the second notification is executed based on the predetermined target operation being performed on the opening/closing body, the opening/closing body may be in the open state in order to illegally execute the predetermined setting-related processing. Also, since the second notification is executed for it, the manager of the gaming hall can recognize the presence or absence of the fraudulent activity. In addition, since the first notification is set to have a higher execution priority than the second notification, it is possible to notify whether or not the predetermined target operation is performed on the opening/closing body, while performing the predetermined notification. It is possible to directly notify that the setting related processing is being performed.

Features αZ4. The gaming machine according to feature αZ3, wherein the setting-related execution means executes processing for notifying a current setting value as the predetermined setting-related processing.

According to the feature αZ4, when the process for confirming the current set value is executed, the first notification is executed, so that the manager of the game hall determines whether or not the set value is confirmed. It becomes possible to confirm.

In addition, with respect to the configuration of the features αZ1 to αZ4, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1-. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the characteristic αZ group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as in the above example, it is necessary to suitably perform the notification, and there is still room for improvement in this respect.

<Characteristic αa group>
Features αa1. Means for executing profit-giving processing in a mode corresponding to the setting value set as the usage target from among the setting values of a plurality of stages corresponding to the player's advantage (the processing of steps S503 and S504 in the main CPU 63 Function to execute)
The current set value is notified based on the occurrence of a specific event (ON operation of the setting key insertion portion 68a) that occurs in a state where the opening/closing body (game machine body 12) is in the open state. Means for executing the setting confirmation process (a function for executing the setting confirmation process in the main CPU 63),
First notification executing means for executing the first notification when the setting confirmation processing is executed (the function of executing the processing of step SG808 of the main CPU 63 in the seventy-fourth embodiment and the sound/light side CPU 353). Function for executing the processing of step SH107 of
Second notification execution means for executing the second notification when a predetermined target operation, which is one of the opening operation and the closing operation, is performed on the opening/closing body (main CPU 63 in the seventy-fourth embodiment). Function for executing the processing in step SG904 and the function for executing the processing in step SH114 of the sound-light side CPU 353).
Equipped with
A gaming machine, wherein the first notification is set to have a higher execution priority than the second notification.

According to the characteristic αa1, since the first notification is executed when the setting confirmation process is executed, the game hall manager confirms that the first notification is executed, and thereby the setting confirmation process is executed. It becomes possible to grasp that the process has been executed. Further, since a predetermined setting confirmation process is executed based on the occurrence of a specific event that occurs when the opening/closing body is in the open state, the opening/closing body is required to execute the setting confirmation process. Need to be opened, and it becomes difficult to execute the setting confirmation process illegally. Further, since the second notification is executed based on the predetermined target operation being performed on the opening/closing body, even if the opening/closing body is opened to illegally execute the setting confirmation process. On the other hand, the second notification is executed. Therefore, it becomes possible for the manager of the game hall to know the presence or absence of the fraudulent activity. Since the first notification is set to have a higher execution priority than the second notification, it is possible to notify whether or not the predetermined target operation has been performed on the opening/closing body, while confirming the setting. It becomes possible to directly notify that the usage processing is being performed.

Feature αa2. The second notification is configured to be executed until a predetermined target related period elapses after the predetermined target operation is performed on the opening/closing body,
When the first notification is executed with priority over the second notification, and the predetermined target related period is set after the predetermined target operation is performed on the opening/closing body. The gaming machine according to the feature αa1, wherein the second notification is executed over the remaining period of the predetermined target related period when the first notification ends before the elapse.

According to the feature αa2, in a configuration in which the first notification has a higher execution priority than the second notification, it becomes possible to execute the second notification after the first notification ends. Even when the second notification is executed after the first notification is completed, the execution period is until the first notification ends after the predetermined target operation is performed on the opening/closing body. The remaining period is obtained by subtracting the required period from the predetermined target related period. This makes it possible to prevent the total execution period of these notifications from becoming excessively long when the second notification is executed after the completion of the first notification.

Feature αa3. The first notification is configured to be executed until a specific related period elapses after the setting confirmation process is executed,
The gaming machine according to feature αa2, wherein the predetermined target related period is set to be longer than the specific related period.

According to the feature αa3, even when the first notification is executed with priority over the second notification, it is possible to ensure the execution period of the second notification after the end of the first notification.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features αa1 to αa3. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αb group>
Features αb1. When a predetermined event occurs due to the execution of a game, history storage execution means (for the main CPU 63 in the 75th embodiment, which stores history information of the corresponding game in the history storage means (normal counter area 231) A function for executing the processing of step SH404),
Information derivation means (main side in the 75th embodiment) for deriving mode information (67th parameter in the 75th embodiment) corresponding to the result of the game using the history information stored in the history storage means A function of executing the processing of step SH508 of the CPU 63),
Profit giving process executing means for executing a profit giving process in a mode corresponding to a set value set as a usage target from a plurality of stages of set values corresponding to a player's advantage (step S503 in the main CPU 63 and A function of executing the process of step S504),
Suggestion effect control means for executing a suggestion effect that enables the player to grasp or predict the set value set as the use target (mainly in the 75th and 76th embodiments) A function of executing the ending process of the side CPU 63 and a function of executing the ending effect control process of the sound emission control device 81),
Depending on the aspect information derived by the information deriving means, aspect difference means for changing the presence or absence of execution of the suggestion effect or the aspect of execution of the suggestion effect (step SH804 to step of the main CPU 63 in the 75th embodiment) A function of executing the processing of SH806, a function of executing the processing of steps SI105 to SI107 of the main CPU 63 in the seventy-sixth embodiment),
A gaming machine characterized by being equipped with.

According to the characteristic αb1, when the predetermined event occurs, the history information corresponding to the predetermined event is stored in the history storage means. By storing the history information in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, by using the history information stored in the history storage means to derive mode information corresponding to the result of the game in a predetermined period, the management result of the game history such as the frequency of occurrence of the predetermined event is grasped. It becomes possible. In addition, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player can confirm that the more advantageous setting value is to be used. You will expect it.

In some cases, a suggestion effect that allows the player to grasp or predict the set value set as the usage target in the above configuration is executed. As a result, the player can expect that the suggestive effect will be executed, and by confirming the suggestive effect, the player can grasp or predict the set value set as the usage target.

In this case, the presence/absence of execution of the suggestive effect or the mode of execution of the suggestive effect differs depending on the mode information derived using the history information. As a result, the suggestion effect can be executed in a mode corresponding to the result of the game in the predetermined period, and the suggestion of the set value set as the usage target can be suitably performed. Therefore, it is possible to make the configuration related to the set value suitable.

Feature αb2. There are predetermined suggestive effects (fourth suggestive effect and fifth suggestive effect) as the suggestive effects,
In the predetermined suggestive effect, when the setting value set as the usage target is a relatively high setting value, the setting value selected as the execution target of the effect or the setting value set as the usage target is relatively high. When the setting value is high, the probability of being selected as a performance execution target is high,
The aspect difference means is characterized in that at least the predetermined suggestion effect is not executed based on that the aspect information derived by the information derivation means is not information of a predetermined normal range. The gaming machine described in αb1.

According to the characteristic αb2, if the mode information indicating the result of the game in the predetermined period is not the information of the normal range, the predetermined suggestion effect is not executed. As a result, a predetermined value indicating that the setting value set as the usage target is a relatively high setting value or that the setting value set as the usage target is a relatively high setting value is high. It is possible to prevent the suggestive effect from being executed even when the result of the game in the predetermined period is not normal.

Feature αb3. There are specific suggestive effects (second suggestive effect and third suggestive effect) as the suggestive effect,
The specific suggestion effect is an effect that is more difficult for the player to predict than when the predetermined suggestion effect is executed as to whether or not the setting value set as a use target is a relatively high setting value,
The gaming machine according to feature αb2, wherein the specific suggestion effect can be executed even if the aspect information derived by the information deriving unit is not information of a predetermined normal range.

According to the characteristic αb3, when the mode information indicating the result of the game in the predetermined period is not the information in the normal range, the mode information indicating the result of the game in the predetermined period is in the normal range in the configuration in which the predetermined suggestion effect is not executed. Even if it is not the information, the specific suggestion effect is executed. As a result, even if the game result in the predetermined period is not normal, it is possible for the player to leave room for predicting the set value.

Feature αb4. There are specific suggestive effects (second suggestive effect and third suggestive effect) as the suggestive effect,
Of the first group (the odd set value) in which the set value set as the use target includes a plurality of set values and the second group (the even set value) that includes the plurality of set values, If the one of the first group and the second group has one of the set values that is selected as the performance execution target or is set as the usage target, the performance of the performance is more than that of the other. It has a high probability of being selected as an execution target,
The first group includes both advantageous setting values and disadvantageous setting values as compared with the setting values included in the second group,
The second group includes both a setting value that is more advantageous and a setting value that is more disadvantageous than the setting values that are included in the first group,
The gaming machine according to feature αb2 or αb3, wherein the specific suggestion effect can be executed even if the aspect information derived by the information deriving unit is not information of a predetermined normal range.

According to the characteristic αb4, when the mode information indicating the result of the game in the predetermined period is not the information in the normal range, the mode information indicating the result of the game in the predetermined period is in the normal range in the configuration in which the predetermined suggestion effect is not executed. Even if it is not the information, the specific suggestion effect is executed. As a result, even if the game result in the predetermined period is not normal, it is possible for the player to leave room for predicting the set value.

Further, the specific suggestion effect is an effect that makes it possible to grasp or predict that the set value set as the use target is either the first group or the second group. Since each of the first group and the second group includes a plurality of setting values, it is possible to know which of the first group and the second group the setting value set as the usage target corresponds to or Even if it can be predicted, it is not possible to grasp or predict the set value itself set as the usage target. Therefore, even if the specific suggestion effect is executed in a situation where the result of the game in the predetermined period is not normal, it is possible to suppress the influence on the player more than when the predetermined suggestion effect is executed.

Feature αb5. The aspect differentiating means is configured to prevent at least the predetermined suggestive effect from being executed in a situation in which the aspect information has not been derived by the information deriving means. Amusement machine.

According to the characteristic αb5, it is not possible to specify whether or not the result of the game in the predetermined period is normal in the situation where the mode information has not yet been derived. Not executed As a result, a predetermined value indicating that the setting value set as the usage target is a relatively high setting value or that the setting value set as the usage target is a relatively high setting value is high. It is possible to prevent the suggestive effect from being executed in a situation where it is not possible to specify whether or not the result of the game in the predetermined period is normal.

Feature αb6. In the situation in which the aspect information has not been derived by the information deriving means, the aspect differentiating means produces an effect similar to the situation in which the aspect information derived by the information deriving means is not the information in the normal range. The game machine according to any one of the features αb2 to αb5, characterized in that the type of the suggestive effect to be executed is determined.

According to the characteristic αb6, in a situation where the aspect information has not been derived yet, the type of suggestive effect that is the execution target of the effect in the same manner as in the situation where the aspect information derived by the information deriving unit is not the information in the normal range. Is determined. As a result, the execution mode of the suggestive effect dedicated to the situation where the mode information has not yet been derived is not required, and thus it is possible to achieve the above-described excellent effect while suppressing the required storage capacity. Become.

Feature αb7. It is provided with a predetermined ball entering means (first operating port 33, second operating port 34) into which a game ball flowing down in the game area can enter.
The profit giving process executing means shifts the game state to an advantageous state (opening/closing execution mode) advantageous to the player as the profit giving process based on the fact that a game ball has entered the predetermined ball entering means. A process for determining whether or not to perform the process, the process being executed in a mode corresponding to the set value set as a use target,
This gaming machine, on the basis of the fact that it is decided to shift the game state to the advantageous state in the profit giving process, advantageous shift means for shifting the game state to the advantageous state (in the 75th embodiment). A function of executing the processing of steps SH608 to SH612 of the main CPU 63),
The history storage executing means stores at least information on the number of game balls entered into the predetermined ball entering means in the history storage means as the history information,
The information derivation means derives, as the aspect information, information corresponding to the frequency of game balls entering the predetermined ball entering means by using the history information stored in the history storage means. The gaming machine according to any one of the features αb1 to αb6.

According to the feature αb7, since the frequency of entering the game ball into the predetermined ball entering means is derived as the mode information, it is possible to manage the frequency of entering the game ball into the predetermined ball entering means. In this case, the presence/absence of execution of the suggestive effect or the mode of execution of the suggestive effect differs depending on the mode information. As a result, it is possible to execute the suggestive effect in a state in which the frequency of the game balls entering the predetermined ball entering means is taken into consideration, and it is appropriate in relation to the frequency of entering the game balls into the predetermined ball entering means. Therefore, it is possible to execute the suggestion effect.

Feature αb8. The suggestion production control means,
The type of the suggestive effect to be the execution target of the effect, the effect selection information group (the set value suggestion lottery table group 541 at the time of the normal suggestion, the suggestion limit time at the time of suggestion limitation) according to the mode corresponding to the set value set as the use target. A type determining means (a function of executing the process of step SH807 of the main CPU 63 in the 75th embodiment) determined by referring to the set value suggestion lottery table group 542),
Suggestion effect execution means for executing the suggestion effect of the type determined by the type determining means (function of executing the processing of steps SH808 and SH809 of the main CPU 63 in the seventy-fifth embodiment and voice emission control) A function of executing the ending effect control process of the device 81),
Equipped with
The effect selection information group is set in plural types corresponding to the contents of the aspect information that can be derived by the information deriving unit,
The aspect differing means causes the type determining means to refer to the effect selection information group of the type corresponding to the aspect information derived by the information deriving means, of the characteristics αb1 to αb7. The gaming machine according to any one of the above.

According to the feature αb8, a plurality of types of effect selection information groups are set in correspondence with the contents of the aspect information, and the effect selection information group of the type corresponding to the aspect information derived by the information deriving means is referred to. , The type of suggestive production to be executed is determined. This makes it possible to reduce the processing load and make the execution mode of the suggestive effect different in correspondence with the mode information derived by the information deriving unit.

Feature αb9. The suggestion production control means,
Refer to the information group for effect selection (the set value suggestion lottery table group 541 at the time of normal suggestion) for the type of the suggestive effect that is the execution target of the effect, in a mode corresponding to the set value set as the use target. A type determining unit (a function of executing the process of step SI104 of the main CPU 63 in the seventy-sixth embodiment) determined by
Suggestion effect execution means for executing the suggestion effect of the type determined by the type determination means (function of executing the processes of step SI108 and step SI109 of the main CPU 63 in the 76th embodiment),
Equipped with
If the type of the suggestive effect determined by the type determining unit does not correspond to the aspect information derived by the information deriving unit, the aspect differenting unit may indicate the type of the suggestion determined by the type determining unit. The gaming machine according to any one of the features αb1 to αb7, characterized in that the effect is not executed.

According to the feature αb9, even if the type of the suggested effect to be the execution target of the effect is determined by referring to the effect selection information group in the mode corresponding to the setting value set as the use target, the information deriving means Depending on the content of the aspect information derived by, the suggestion effect of the determined type may not be executed. Thereby, it is possible to make the execution mode of the suggested effect correspond to the mode information derived by the information deriving means while suppressing an increase in the storage capacity for storing the effect selection information group in advance.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features αb1 to αb9. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1-. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αc group>
Features αc1. When a predetermined event occurs due to the execution of a game, history storage execution means (for the main CPU 63 in the 75th embodiment, which stores history information of the corresponding game in the history storage means (normal counter area 231) A function for executing the processing of step SH404),
Information derivation means (main side in the 75th embodiment) for deriving mode information (67th parameter in the 75th embodiment) corresponding to the result of the game using the history information stored in the history storage means A function of executing the processing of step SH508 of the CPU 63),
Profit giving process executing means for executing a profit giving process in a mode corresponding to a set value set as a usage target from a plurality of stages of set values corresponding to a player's advantage (step S503 in the main CPU 63 and A function of executing the process of step S504),
Suggestion effect control means for executing a suggestion effect that enables the player to grasp or predict the set value set as the use target (mainly in the 75th and 76th embodiments) A function of executing the ending process of the side CPU 63 and a function of executing the ending effect control process of the sound emission control device 81),
Equipped with
The suggestion production control means,
Refer to the information group for effect selection (the set value suggestion lottery table group 541 at the time of normal suggestion) for the type of the suggestive effect that is the execution target of the effect, in a mode corresponding to the set value set as the use target. A type determining unit (a function of executing the process of step SI104 of the main CPU 63 in the seventy-sixth embodiment) determined by
Suggestion effect execution means for executing the suggestion effect of the type determined by the type determination means (function of executing the processes of step SI108 and step SI109 of the main CPU 63 in the 76th embodiment),
Equipped with
In the present gaming machine, if the type of the suggestive effect determined by the type determining means does not correspond to the aspect information derived by the information deriving means, the suggestive effect of the type determined by the type determining means Is provided with a mode different means (a function for executing the processing of steps SI105 to SI107 of the main CPU 63 in the seventy-sixth embodiment) for preventing the execution of the above.

According to the characteristic αc1, when the predetermined event occurs, the history information corresponding to the predetermined event is stored in the history storage means. By storing the history information in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, by using the history information stored in the history storage means to derive mode information corresponding to the result of the game in a predetermined period, the management result of the game history such as the frequency of occurrence of the predetermined event is grasped. It becomes possible. In addition, since the setting value to be used is set from the setting values of a plurality of stages corresponding to the advantage of the player, the player can confirm that the more advantageous setting value is to be used. You will expect it.

In some cases, a suggestion effect that allows the player to grasp or predict the set value set as the usage target in the above configuration is executed. As a result, the player can expect that the suggestive effect will be executed, and by confirming the suggestive effect, the player can grasp or predict the set value set as the usage target.

In this case, even if the type of suggestive production to be the execution target of the production is determined by referring to the production selection information group in the mode corresponding to the setting value set as the usage target, the information deriving unit derives it. Depending on the content of the performed mode information, the determined type of suggestive effect may not be executed. Thereby, it is possible to make the execution mode of the suggested effect correspond to the mode information derived by the information deriving means while suppressing an increase in the storage capacity for storing the effect selection information group in advance.

Feature αc2. There are predetermined suggestive effects (fourth suggestive effect and fifth suggestive effect) as the suggestive effects,
In the predetermined suggestive effect, when the setting value set as the usage target is a relatively high setting value, the setting value selected as the execution target of the effect or the setting value set as the usage target is relatively high. When the setting value is high, the probability of being selected as a performance execution target is high,
In the aspect differentiating means, the type of the suggestive effect determined by the type determining means in the situation where the aspect information derived by the information deriving means is not information of a predetermined normal range is the predetermined suggestive effect. In this case, the gaming machine described in the feature αc1 is characterized in that the predetermined suggestion effect is not executed.

According to the characteristic αc2, the predetermined suggestion effect is not executed when the aspect information indicating the result of the game in the predetermined period is not the information of the normal range. As a result, a predetermined value indicating that the setting value set as the usage target is a relatively high setting value or that the setting value set as the usage target is a relatively high setting value is high. It is possible to prevent the suggestive effect from being executed even when the result of the game in the predetermined period is not normal.

Feature αc3. There are specific suggestive effects (second suggestive effect and third suggestive effect) as the suggestive effect,
The specific suggestion effect is an effect that is more difficult for the player to predict than when the predetermined suggestion effect is executed as to whether or not the setting value set as a use target is a relatively high setting value,
The gaming machine according to feature αc2, wherein the specific suggestion effect can be executed even if the aspect information derived by the information deriving unit is not information of a predetermined normal range.

According to the feature αc3, when the mode information indicating the result of the game in the predetermined period is not the information in the normal range, the mode information indicating the result of the game in the predetermined period is in the normal range in the configuration in which the predetermined suggestion effect is not executed. Even if it is not the information, the specific suggestion effect is executed. As a result, even if the game result in the predetermined period is not normal, it is possible for the player to leave room for predicting the set value.

Feature αc4. There are specific suggestive effects (second suggestive effect and third suggestive effect) as the suggestive effect,
Of the first group (the odd set value) in which the set value set as the use target includes a plurality of set values and the second group (the even set value) that includes the plurality of set values, If the one of the first group and the second group has one of the set values that is selected as the performance execution target or is set as the usage target, the performance of the performance is more than that of the other. It has a high probability of being selected as an execution target,
The first group includes both advantageous setting values and disadvantageous setting values as compared with the setting values included in the second group,
The second group includes both a setting value that is more advantageous and a setting value that is more disadvantageous than the setting values that are included in the first group,
The gaming machine according to feature αc2 or αc3, wherein the specific suggestion effect can be executed even if the aspect information derived by the information deriving unit is not information of a predetermined normal range.

According to the characteristic αc4, when the mode information indicating the result of the game in the predetermined period is not the information in the normal range, the mode information indicating the result of the game in the predetermined period is in the normal range in the configuration in which the predetermined suggestion effect is not executed. Even if it is not the information, the specific suggestion effect is executed. As a result, even if the game result in the predetermined period is not normal, it is possible for the player to leave room for predicting the set value.

Further, the specific suggestion effect is an effect that makes it possible to grasp or predict that the set value set as the use target is either the first group or the second group. Since each of the first group and the second group includes a plurality of setting values, it is possible to know which of the first group and the second group the setting value set as the usage target corresponds to or Even if it can be predicted, it is not possible to grasp or predict the set value itself set as the usage target. Therefore, even if the specific suggestion effect is executed in a situation where the result of the game in the predetermined period is not normal, it is possible to suppress the influence on the player more than when the predetermined suggestion effect is executed.

Feature αc5. The aspect differentiating means is configured to prevent at least the predetermined suggestive effect from being executed in a situation where the aspect information has not been derived by the information deriving means, according to any one of characteristics αc2 to αc4. Amusement machine.

According to the characteristic αc5, it is not possible to specify whether or not the result of the game in the predetermined period is normal in the situation where the aspect information has not been derived yet, so in such a situation, at least the predetermined suggestion effect is produced. Not executed As a result, a predetermined value indicating that the setting value set as the usage target is a relatively high setting value or that the setting value set as the usage target is a relatively high setting value is high. It is possible to prevent the suggestive effect from being executed in a situation where it is not possible to specify whether or not the result of the game in the predetermined period is normal.

Feature αc6. In the situation in which the aspect information has not been derived by the information deriving means, the aspect differentiating means produces an effect similar to the situation in which the aspect information derived by the information deriving means is not the information in the normal range. The game machine according to any one of the features αc2 to αc5, wherein the type of the suggestive effect to be executed is determined.

According to the characteristic αc6, in the situation where the aspect information has not been derived yet, the type of suggestive effect that is the execution target of the effect in the same manner as in the situation where the aspect information derived by the information deriving unit is not the information in the normal range. Is determined. As a result, the execution mode of the suggestive effect dedicated to the situation where the mode information has not yet been derived is not required, and thus it is possible to achieve the above-described excellent effect while suppressing the required storage capacity. Become.

Features αc7. It is provided with a predetermined ball entering means (first operating port 33, second operating port 34) into which a game ball flowing down in the game area can enter.
The profit giving process executing means shifts the game state to an advantageous state (opening/closing execution mode) advantageous to the player as the profit giving process based on the fact that a game ball has entered the predetermined ball entering means. A process for determining whether or not to perform the process, the process being executed in a mode corresponding to the set value set as a use target,
This gaming machine, on the basis of the fact that it is decided to shift the game state to the advantageous state in the profit giving process, advantageous shift means for shifting the game state to the advantageous state (in the 75th embodiment). A function of executing the processing of steps SH608 to SH612 of the main CPU 63),
The history storage executing means stores at least information on the number of game balls entered into the predetermined ball entering means in the history storage means as the history information,
The information derivation means derives, as the aspect information, information corresponding to the frequency of game balls entering the predetermined ball entering means by using the history information stored in the history storage means. The gaming machine according to any one of the features αc1 to αc6.

According to the feature αc7, the frequency of the game balls entering the predetermined ball entering means is derived as the mode information, so that the frequency of entering the game balls into the predetermined ball entering means can be managed. In this case, the presence/absence of execution of the suggestive effect or the mode of execution of the suggestive effect differs depending on the mode information. As a result, it is possible to execute the suggestive effect in a state in which the frequency of the game balls entering the predetermined ball entering means is taken into consideration, and it is appropriate in relation to the frequency of entering the game balls into the predetermined ball entering means. Therefore, it is possible to execute the suggestion effect.

For the configurations of the features αc1 to αc7, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1-. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the inventions related to the characteristic αa group, the αb group, and the αc group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as exemplified above, it is necessary to make the configuration relating to the set value that determines the advantage of the gaming machine suitable, and there is still room for improvement in this respect.

<Characteristic αd group>
Features αd1. When a predetermined event occurs due to the execution of a game, history storage execution means (normal entrance management processing in the main CPU 63) for storing history information of the game corresponding to it in the history storage means (normal counter area 231) Function to execute)
Information derivation means (function of executing the process of step S8601 in the main CPU 63) for deriving mode information (base value) corresponding to the result of the game using the history information stored in the history storage means,
Mode information display control means (main CPU 63) for controlling the display of the information display means (first to fourth notification display devices 201 to 204) so that the display corresponding to the mode information derived by the information deriving means is performed. Function for executing display processing and second timer interrupt processing in)
Equipped with
The aspect information display control means changes the information display means to a specific event corresponding state based on occurrence of a specific event (detection of an illegal electric wave, detection of an illegal magnetism, detection of an abnormal vibration). A game machine provided with an event handling means (a function of executing the processing of steps SI305 to SI311 of the main CPU 63 in the 77th embodiment, a function of executing the processing of step SI401 of the main CPU 63). ..

According to the characteristic αd1, when the predetermined event occurs, the history information corresponding to the predetermined event is stored in the history storage means. By storing the history information in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, the mode information corresponding to the result of the game is derived by using the history information stored in the history storage means, and the information display means performs the display corresponding to the derived mode information. Thereby, it becomes possible to grasp the management result of the game history such as the frequency of occurrence of the predetermined event. Further, the information display means changes to the specific event corresponding state based on the occurrence of the specific event. Therefore, it is possible to grasp that the specific event has occurred based on the information display means being in the specific event corresponding state. This makes it easy to determine whether or not a specific event has occurred.

Feature αd2. The gaming machine according to feature αd1, wherein the specific event corresponding state is a non-display state in which no display is made on the information display means.

According to the feature αd2, it is possible to grasp that the specific event has occurred based on the fact that the information display means is in the non-display state. It is possible to easily grasp that the specific event has occurred, without pre-storing data for displaying the occurrence of the specific event.

Feature αd3. Based on the occurrence of the specific event, a predetermined stop means (a state in which the game stop flag is set to "1") in which the progress of the game is stopped (step SI302 to step in the main CPU 63) The game machine described in the feature αd1 or αd2, which is provided with a function of executing the processing of SI303.

According to the characteristic αd3, in the configuration having the configuration of the characteristic αd1 and the information display means is changed to the specific event corresponding state based on the occurrence of the specific event, the predetermined stop state is generated based on the occurrence of the specific event. Is set to. Therefore, it is possible to grasp that the information display unit is in the predetermined stop state based on the state in which the information display unit corresponds to the specific event. This makes it easy to determine whether or not the vehicle is in the predetermined stop state.

Feature αd4. The aspect information display control means,
Display control means for transmitting display data (display data signal, display clock signal) corresponding to display contents to be displayed on the information display means (function for executing second timer interrupt processing in the main CPU 63);
Display execution means (display IC 266) for performing display setting on the information display means so that the display content corresponds to the display data when the display data is transmitted by the display control means,
Is equipped with
The specific event response means stores change data (all “0” type data, all “0” display data) for changing the information display means to the specific event response state when the specific event occurs. Change data transmission means for transmitting from the display control means (function for executing the processing of steps SI306 to SI310 of the main CPU 63 in the 77th embodiment);
The gaming machine according to any one of the features αd1 to αd3.

According to the feature αd4, the information display means is changed to the specific event mode state based on the change data transmitted when the specific event occurs, so that the early occurrence based on the occurrence of the specific event occurs. The information display means can be changed to a specific event corresponding state. As a result, it is possible to reduce the possibility of misunderstanding whether or not a specific event has occurred.

Feature αd5. The aspect information display control means,
Display control means for transmitting display data (display data signal, display clock signal) corresponding to display contents to be displayed on the information display means (function for executing second timer interrupt processing in the main CPU 63);
Display execution means (display IC 266) for performing display setting on the information display means so that the display content corresponds to the display data when the display data is transmitted by the display control means,
Is equipped with
The information display means maintains the display corresponding to the display data by transmitting the display data so that the next display setting is performed before the display corresponding to the display data cannot be maintained. Yes,
When the specific event occurs, the specific event response means is the display control means until the state corresponding to the occurrence of the specific event (the state where the game stop flag is set to "1") is released. The gaming machine according to any one of the features αd1 to αd4, wherein the display data is not transmitted by the above.

According to the characteristic αd5, when the specific event occurs, the display data is not transmitted until the state corresponding to the occurrence of the specific event is released. Therefore, in the information display means until the state is released. The specific event response state can be continued. Thereby, it is possible to easily determine whether or not the state corresponds to the occurrence of the specific event based on the state of the information display means.

Feature αd6. The history storage execution means, even in a situation where the information display means is in the specific event corresponding state based on the occurrence of the specific event, when the predetermined event occurs, the history of the game corresponding thereto The gaming machine according to any one of the features αd1 to αd5, wherein information is stored in the history storage means.

According to the feature αd6, the history information of the game corresponding to the occurrence of the predetermined event after the occurrence of the specific event can be stored in the history storage means. Thereby, it is possible to derive the mode information corresponding to the result of the game by using the history information of the game including the history information of the game corresponding to the predetermined event that occurs after the occurrence of the specific event.

Feature αd7. An abnormality detection unit (a radio wave detection sensor 551, a magnetic detection sensor 552, a vibration detection sensor 553) for detecting a predetermined abnormal state of the gaming machine is provided,
The gaming machine according to any one of features αd1 to αd6, wherein the specific event is that the predetermined abnormal state is detected.

According to the characteristic αd7, when the predetermined abnormal state is detected, the information display means becomes the specific event corresponding state. Therefore, it is possible to know that the predetermined abnormal state is detected based on the information display means being in the specific event corresponding state. Thereby, it is possible to easily determine whether or not the predetermined abnormal state is detected.

Feature αd8. Predetermined information display means (special figure display section 37a, special figure reservation display section 37b, general figure display section 38a, general figure reservation display section 38b) provided at a position visible from the outside and displaying predetermined information. ,
Predetermined information display control means (a function of executing the processing of step SI401 to step SI402 and step SI409 to step SI415 in the main CPU 63) for controlling the display of the predetermined information display means so that the predetermined information is displayed;
Equipped with
The predetermined information display control means changes the predetermined information display means to the specific event handling state based on the occurrence of the specific event (executes the processing of steps SI305 to SI311 in the main CPU 63). The game machine according to any one of the features αd1 to αd7, which has a function to perform, a function to execute the process of step SI401 in the main CPU 63).

According to the characteristic αd8, in the configuration having the configuration of the characteristic αd1 and changing the information display means to the specific event corresponding state based on the occurrence of the specific event, predetermined information is displayed based on the occurrence of the specific event. The means is changed to the specific event handling state. Since the states of the information display means and the predetermined information display means are changed to the states corresponding to the occurrence of the specific event based on the occurrence of the specific event, the state of only the information display means is changed. By comparison, the determination as to whether or not a specific event has occurred can be made easier. Further, the predetermined information display means is provided at a position visible from the outside. Therefore, it can be confirmed from the outside of the gaming machine that the specific event has occurred, and the determination as to whether or not the specific event has occurred can be further facilitated.

Feature αd9. The gaming machine according to feature αd8, wherein the particular event handling state is a non-display state in which no display is made on the predetermined information display means.

According to the feature αd9, it is possible to easily understand from the outside that a specific event has occurred based on the predetermined information display means being in the non-display state.

In addition, with respect to the configurations of the features αd1 to αd9, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1-. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the characteristic αd group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as exemplified above, it is necessary to suitably perform the display control of the information display means, and there is still room for improvement in this respect.

<Characteristic αe group>
Features αe1. Specific triggers that occur after the start of the supply of the operating power (in the 77th, 79th to 81st and the 88th embodiments, the demo start timer counter 554a is started to be updated after the sound-light side RAM clear processing, in the 78th embodiment. A predetermined trigger (in the 77th, 79th to 81st, and 88th embodiments) that occurs periodically with reference to the storage of the reference time information of the demonstration effect (in the 77th, 79th, 81st, and 88th embodiments, the value of the timer counter 554a for starting a demo reaches the maximum value; In the 78th embodiment, a predetermined trigger specifying means (77th, 79th to 81st, 88th) for specifying whether or not the elapsed time from the reference time of the demonstration effect is an integral multiple of 15 seconds). Function for executing the processing of steps SI707 and SI712 in the sound-light side CPU 353 in the embodiment of the present invention, and a function of executing the processing of steps SI909 and SI914 in the sound-light side CPU 353 in the seventy-eighth embodiment),
Execution of predetermined effect control means (77th, 79th to 81st, 88th) for starting a predetermined effect (demo effect) based on the fact that the predetermined opportunity is specified by the predetermined opportunity specifying means. In the embodiment, the function of executing the process of step SI709 in the sound/light side CPU 353, and in the 78th embodiment, the function of executing the process of step SI911 in the sound/light side CPU 353).
A gaming machine characterized by being equipped with.

According to the feature αe1, a predetermined trigger is generated periodically based on the specific trigger. For this reason, when the generation cycle of the predetermined triggers based on the specific triggers is the same in a plurality of gaming machines, the generation timings of the specific triggers are aligned by aligning the generation timings of the specific triggers. Is possible. Further, the predetermined effect is started based on the fact that the predetermined trigger has occurred. Therefore, by aligning the timing of occurrence of the predetermined trigger in the plurality of gaming machines, it is possible to align the start timing of the predetermined effect in the plurality of gaming machines. As a result, it is possible to give the predetermined effect a sense of unity and increase the player's interest in the gaming machine.

Feature αe2. A start-time process executing means (a function of executing the processes of steps SB101 to SB122 in the main CPU 63) for executing the process at the start of supply of the operating power is started;
When the first processing (setting value update processing, setting value confirmation processing) is executed in the processing at the start of supply and the second processing (processing of step SB113 in the main CPU 63, processing of step SB118 in the main CPU 63) When the process is performed, the period required from the start of the process at the start of supply to the completion of the process varies,
Regardless of whether the first process is executed or the second process is executed in the process at the start of supply, from when the supply of the operating power is started to when the specific trigger is generated. The gaming machine according to feature αe1, which has a configuration that does not affect a required period.

According to the characteristic αe2, when the first process is executed and when the second process is executed in the process at the start of supply, from the start of the supply of the operating power to the occurrence of the specific trigger. It is possible to prevent a difference in required period. Therefore, when the supply of operating power to a plurality of gaming machines is started at the same time, the gaming machine in which the first processing is executed and the gaming machine in which the second processing is executed in the processing at the start of supply. It is possible to align the timing of occurrence of the specific trigger in. With the configuration of the above feature αe1, the predetermined trigger is periodically generated based on the specific trigger. Therefore, by aligning the occurrence timings of the specific triggers in the plurality of gaming machines, it is possible to align the reference of the occurrence timings of the predetermined triggers in the plurality of gaming machines.

Features αe3. Whether the first process is executed or the second process is executed in the process at the start of supply has a configuration that does not affect the cycle in which the predetermined trigger occurs. The gaming machine described in the characteristic αe2.

According to the characteristic αe3, the gaming machine in which the first process is executed in the process at the start of supply and the gaming machine in which the second process is executed in the process at the start of supply have a predetermined opportunity based on the specific opportunity. The generated cycles can be the same cycle. By having the configuration of the above characteristic αe2, the operation is performed in the gaming machine in which the first processing is executed in the processing at the start of supply and in the gaming machine in which the second processing is executed in the processing at the start of supply. There is no difference in the time required from the start of power supply to the occurrence of a specific trigger. Therefore, by starting the supply of operating power to a plurality of gaming machines at the same time, the gaming machine in which the first processing is executed in the processing at the start of supply and the second processing in the processing at the start of supply are performed. The timing of occurrence of the specific trigger can be aligned with the executed gaming machine. In the configuration including the configuration of the characteristic αe1 described above, in which the predetermined effect is started based on the fact that the predetermined trigger is specified, the generation timing of the specific trigger in a plurality of gaming machines and the specific trigger As a result, the timings at which the predetermined effects are started can be aligned in the plurality of gaming machines by aligning the generation cycles of the predetermined triggers that occur periodically.

It has the configuration of the above characteristic αe2 and is required from the start of the supply start process to the completion thereof depending on whether the first process is executed or the second process is executed during the supply start process. The period varies. In this configuration, when the supply of operating power to a plurality of gaming machines is started at the same time, the gaming machine in which the first processing is executed in the processing at the start of supply and the second processing in the processing at the start of supply By enabling the predetermined effect to be started simultaneously with the game machine on which the game is executed, the game machine on which the first process is executed and the game machine on which the second process is executed are determined based on the start timing of the predetermined effect. It is possible to prevent it from being easily performed.

Features αe4. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (function of executing the process of step SB311 in the main CPU 63),
When a supply of operating power is started, a predetermined setting-related operation (ON operation of the setting key insertion part 68a for executing the set value updating process and pressing of the reset button 68c, or a process for confirming the setting is executed. Setting-related execution means (main CPU 63) that executes a predetermined setting-related process relating to the set value as the first process in the process at the start of supply based on the fact that the setting key insertion section 68a has been turned ON). Function for executing the setting value updating process in (2), a function for executing the setting confirmation process in the main CPU 63),
Equipped with
The gaming machine according to feature αe2 or αe3, wherein the second process is performed based on the fact that the predetermined setting-related operation is not performed when supply of operating power is started. ..

According to the feature αe4, in the process at the start of supply, the predetermined setting-related process is executed based on the fact that the predetermined setting-related operation is performed when the supply of the operating power is started, and the predetermined setting-related operation is performed. The second processing is executed based on the fact that the above is not performed. By providing the configuration of the above characteristic αe2, the supply of the operating power is started in the gaming machine in which the predetermined setting-related processing is executed in the processing at the start of supply and the gaming machine in which the second processing is executed. It is possible to prevent a difference from occurring in the period required from the occurrence of the event to the occurrence of the specific trigger. With the configuration of the above characteristic αe1, the configuration is such that a predetermined trigger is periodically generated based on the specific trigger, and the predetermined effect is started based on the fact that the predetermined trigger is identified. is there. In the configuration, in the gaming machine in which the predetermined setting-related processing is executed in the processing at the start of supply and in the gaming machine in which the second processing is executed, a specific trigger occurs after the supply of the operating power is started. It is possible to prevent the gaming machine in which the predetermined setting-related processing is executed based on the start timing of the predetermined effect from being easily identified by preventing a difference in the period required until ..

Features αe5. A main control unit (MPU 62) having a start-time process execution unit (a function of executing the processes of steps SB101 to SB122 in the main CPU 63) that executes a process at the start of supply when the supply of operating power is started;
An effect control means (sound-light side MPU 352) having the predetermined trigger specifying means and the predetermined effect control means,
Equipped with
The gaming machine according to any one of features αe1 to αe4, wherein the specific trigger is generated when supply of operating power to the effect control unit is started.

According to the characteristic αe5, in the configuration in which the specific trigger is generated when the supply of the operating power to the effect control means is started, the predetermined trigger for specifying whether or not the predetermined trigger that regularly occurs on the basis of the specific trigger has occurred The opportunity specifying means is provided in the effect control means. This facilitates the grasp of the specific trigger by the predetermined trigger identifying means, and also facilitates the grasp of the predetermined trigger that occurs periodically on the basis of the specific trigger.

Features αe6. The main control means, when the processing at the start of supply is completed or when the processing is completed, predetermined start correspondence information (normal recovery command, clear recovery command, confirmation recovery command, or A predetermined transmission means (a function for executing the processing of steps SB113 and SB118 in the main CPU 63, a function of executing the processing of step SB207 in the main CPU 63, and a processing of step SB314 in the main CPU 63 for transmitting the update return command) Function to execute)
The effect control means, when receiving the predetermined start correspondence information, executes the information correspondence processing corresponding to the predetermined start correspondence information (in the 77th, 81st, and 88th embodiments, step SI504 to step in the sound-light side CPU 353). A function of executing the processing of SI517, a function of executing the processing of steps SI803 to SI816 in the 78th embodiment, and a function of executing the processing of steps SJ104 to SJ119 in the 79th and 80th embodiments). Cage,
A characteristic αe5 characterized in that the period required from the start of the supply of the operating power to the reception of the predetermined start correspondence information by the effect control means does not affect the cycle in which the predetermined trigger occurs. Amusement machine.

According to the characteristic αe6, the cycle in which the predetermined trigger occurs is not affected by the period required from the start of the supply of the operating power until the performance control unit receives the predetermined start correspondence information. Further, with the configuration of the above feature αe1, the predetermined effect is started based on the fact that a predetermined trigger has occurred. Therefore, it is easy to specify the content of the processing performed in the main control means from the start of the supply of the operating power until the main control means transmits the predetermined start correspondence information, based on the cycle in which the predetermined effect is started. Can be prevented.

Features αe7. A start-time process executing means (a function of executing the processes of steps SB101 to SB122 in the main CPU 63) for executing the process at the start of supply of the operating power is started;
The predetermined effect control means starts the predetermined effect on the basis of the fact that the predetermined trigger specifying means specifies that the predetermined trigger has occurred after the processing at the start of supply is completed. The gaming machine according to any one of features αe1 to αe6.

According to the feature αe7, it is possible to prevent the predetermined effect from being started in the situation where the process at the start of supply is being executed. In addition, after the processing at the start of supply is completed, the predetermined effect is started based on the fact that the predetermined trigger is generated. Therefore, even if the end timing of the process at the start of supply is shifted in a plurality of gaming machines, if the timing of occurrence of the predetermined trigger is aligned in the plurality of game machines, after the processing at the start of supply is completed It is possible to align the start timing of the predetermined effect in.

Feature αe8. Specific effect control means (function for executing steps SI603 to SI614 in the sound-light side CPU 353) for executing a specific effect (game time effect, effect for opening/closing execution mode) which is executed with priority over the predetermined effect. ),
The predetermined effect control means starts the predetermined effect based on the fact that the predetermined trigger specifying means specifies that the predetermined trigger has occurred after the specific effect ends. The gaming machine according to any one of αe1 to αe7.

According to the feature αe8, it is possible to prevent the predetermined effect from being started in the situation where the specific effect is being executed. Further, after the specific effect is finished, the predetermined effect is started based on the fact that the predetermined trigger is generated. For this reason, even if the end timing of the specific effect is shifted in a plurality of gaming machines, if the timing of occurrence of the predetermined trigger is aligned in the plurality of gaming machines, the start timing of the predetermined effect after the end of the specific effect Can be arranged.

Feature αe9. At least a changing unit that changes the timing at which the predetermined trigger first occurs (in the 79th embodiment, the function of executing the processing of steps SJ201 to SJ204 in the sound-light side CPU 353, in the 80th embodiment, in the sound-light side CPU 353). Any one of the characteristics αe1 to αe8 characterized by having a function of executing the processing of steps SJ301 to SJ304, and a function of executing the processing of step SK716 in the sound-light side CPU 353 in the 88th embodiment. The game machine described.

According to the feature αe9, it is possible to change at least the timing at which the predetermined trigger first occurs. Further, with the configuration of the above feature αe1, the predetermined effect is started based on the fact that a predetermined trigger has occurred. For this reason, when the supply of the operating power to the plurality of gaming machines is started at the same time, the timing of occurrence of the predetermined trigger is different in the plurality of gaming machines according to the variation mode of the timing at which the predetermined trigger first occurs. In addition to the timing, the start timing of the predetermined effect can be different timing. By providing a fluctuating means and intentionally creating a situation in which the timing of occurrence of the predetermined trigger is shifted in a plurality of gaming machines, specific processing such as processing for making advantageous settings for the player based on the start timing of the predetermined effect It is possible to prevent the gaming machine on which the processing has been executed from being easily specified.

Feature αe10. The fluctuating means fluctuates the timing at which the predetermined trigger first occurs,
The gaming machine according to feature αe9, wherein the variation mode of the predetermined trigger by the changing unit does not affect the generation cycle of the predetermined trigger after the first generation timing of the predetermined trigger.

According to the characteristic αe10, the variation mode of the predetermined trigger by the changing unit does not affect the generation cycle of the predetermined trigger after the first generation timing of the predetermined trigger. Further, the predetermined effect is started based on the fact that the constitution of the characteristic αe1 is provided and it is specified that the predetermined trigger has occurred. Therefore, it is possible to prevent the variation mode of the predetermined trigger from being specified based on the cycle in which the predetermined effect is started after the first occurrence timing of the predetermined trigger.

In addition, when the supply of operating power to a plurality of gaming machines is started at the same time, some gaming machines in which the variation mode of the first occurrence timing of the predetermined trigger is the same among the plurality of gaming machines, It is possible to align the timing of occurrence of the predetermined trigger of. Further, it is possible to increase the possibility that a situation occurs in which the timing of occurrence of the predetermined trigger in some of the gaming machines and the timing of occurrence of the predetermined trigger in the remaining gaming machines are deviated. Since the predetermined effect is started on the basis that it is specified that the predetermined opportunity has occurred, if the situation arises, the start timing of the predetermined effect should be aligned in some gaming machines. As a result, it is possible to increase the player's interest in the gaming machine by giving a sense of unity to the predetermined effect. In addition, it is presumed that the advantageous settings for the player have been made to the remaining game machines whose start timings of the predetermined effects are different from those of the part of the game machines. It becomes possible to raise the interest of the player.

Feature αe11. Main control means (MPU 62) to which backup power for storing and holding information is supplied in a situation where supply of operating power is stopped;
Effect control means (sound-light side MPU 352) that has the changing means and is not supplied with backup power for storing and holding information in a situation where supply of operating power is stopped,
Equipped with
The main control means provides the effect control means with variation information (random number information for lottery in the 79th and 80th embodiments) for varying the timing at which the predetermined trigger first occurs. The gaming machine according to the characteristic αe9 or αe10.

According to the characteristic αe11, it is possible to adopt a configuration in which the fluctuation information is stored and held by the main control means when the supply of operating power is stopped. Thereby, a predetermined trigger is first generated by using the fluctuation information stored in the main control unit at the time of the previous stop of the supply of the operating power, while the configuration for supplying the backup power to the effect control unit is not provided. It is possible to change the timing.

Feature αe12. The main control means,
A predetermined storage means (main side RAM 65) in which the fluctuation information is stored,
Predetermined initialization means (main RAM side) for executing predetermined initialization processing (first RAM clear processing, second RAM clear processing) for initializing a storage area to be initialized in the predetermined storage means when supply of operating power is started. A function of executing the processing of step SB117 in the CPU 63, a function of executing the processing of step SB313 in the main CPU 63),
A non-predetermined storage means (transmission random number storage counter 556 in the 79th and 80th embodiments) excluded from the target of the predetermined initialization processing in the predetermined storage means;
Equipped with
When the supply of the operating power is started, the fluctuation information stored in the predetermined storage means is stored in the non-predetermined storage means before the predetermined initialization processing is executed. The gaming machine described in the feature αe11.

According to the feature αe12, the fluctuation information is stored in the non-predetermined storage means before the predetermined initialization processing is executed, so that the predetermined storage means stores and holds the operating power in a situation where the supply of operating power is stopped. It is possible to avoid clearing the change information that has been used, and to provide the change information to the effect control unit.

Features αe13. The variation means executes variation lottery processing for determining a variation manner of the timing at which the predetermined trigger occurs (in the 79th embodiment, the processing of steps SJ201 to SJ203 in the sound-light side CPU 353 is performed. A function to execute the processing of steps SJ301 to SJ303 in the sound-light side CPU 353 in the 80th embodiment, and a function to execute the processing of SK716 in the sound-light side CPU 353 in the 88th embodiment). The gaming machine according to any one of the features αe9 to αe12.

According to the characteristic αe13, since the timing at which the predetermined trigger is generated is changed based on the lottery result of the variable lottery process, each variation mode of the timing at which the predetermined trigger is generated with the probability set at the design stage is generated. It is possible to

In addition, with respect to the configurations of the features αe1 to αe13, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1-. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, and features βA1 to βA. 4. Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αf group>
Features αf1. Specific occasion (in the 77th, 79th to 81st and the 88th embodiments, the demo start timer counter 554a is started to be updated after the sound-light side RAM clearing process, and in the 78th embodiment, the demonstration effect reference time information is stored. ) As a reference, a predetermined trigger (in the 77th, 79th to 81st, and 88th embodiments, the value of the demo start timer counter 554a reaches a maximum value, and in the 78th embodiment, demonstration effect). Sound timing side CPU 353 in the embodiments of the 77th, 79th to 81st, and 88th embodiments, which specifies whether or not the elapsed time from the reference time of 10 becomes an integral multiple of 15 seconds). Function for executing the processing of step SI707 and step SI712 in step 78, and a function for executing the processing of step SI909 and step SI914 in the sound-light side CPU 353 in the 78th embodiment).
Predetermined state setting means for setting a predetermined state (start waiting state in the 77th to 81st and 88th embodiments) (function of executing the process of step SI510 of the sound-light side CPU 353 in the 77th embodiment, sound light) The function of the side CPU 353 for performing the processing of step SI705, the function of the sound/light side CPU 353 for performing the processing of step SI809 of the 78th embodiment, the function of the sound/light side CPU 353 for performing the processing of step SI910, and the 79th embodiment. Function of executing the process of step SJ112 of the sound-light side CPU 353 in the embodiment),
Predetermined effect control means (77th, 79th to 81st) that starts predetermined effect (demo effect) based on the fact that the predetermined trigger has occurred in the predetermined state specified by the predetermined trigger specifying means. 88th embodiment, a function of executing the process of step SI709 in the sound-light side CPU 353, and a function of executing the process of step SI911 of the sound-light side CPU 353 in the 78th embodiment).
Equipped with
The predetermined effect control means does not start the predetermined effect even if the predetermined trigger occurs in a state that is not the predetermined state (a state in which "1" is not set in the waiting state flag 555b), and A game machine characterized in that the predetermined effect is not started when the predetermined trigger has not occurred even if a predetermined state is reached.

According to the feature αf1, a predetermined trigger is generated periodically based on the specific trigger. For this reason, when the generation cycle of the predetermined triggers based on the specific triggers is the same in a plurality of gaming machines, the generation timings of the specific triggers are aligned by aligning the generation timings of the specific triggers. Is possible. Further, the predetermined effect is started based on the fact that the predetermined trigger is generated in the predetermined state. Therefore, by aligning the timing of occurrence of the predetermined trigger in the plurality of gaming machines, it becomes possible to align the start timing of the predetermined effect in a predetermined state in the plurality of gaming machines. Further, when the timings of occurrence of the predetermined triggers are aligned in the plurality of gaming machines, even if the timings of the predetermined states are different, the predetermined effect is produced in the plurality of gaming machines after the predetermined state is reached. The start timing can be aligned. As a result, it is possible to give the predetermined effect a sense of unity and increase the player's interest in the gaming machine. Furthermore, in a state other than the predetermined state, it is possible to prevent the predetermined effect from being started even if a predetermined trigger occurs.

Features αf2. A start-time process executing means (a function of executing the processes of steps SB101 to SB122 in the main CPU 63) for executing the process at the start of supply of the operating power is started;
When the first processing (setting value update processing, setting value confirmation processing) is executed in the processing at the start of supply and the second processing (processing of step SB113 in the main CPU 63, processing of step SB118 in the main CPU 63) When the process is performed, the period required from the start of the process at the start of supply to the completion of the process varies,
Regardless of whether the first process is executed or the second process is executed in the process at the start of supply, from when the supply of the operating power is started to when the specific trigger is generated. The gaming machine according to feature αf1, which has a configuration that does not affect a required period.

According to the characteristic αf2, when the first process is executed in the process at the start of supply and when the second process is executed, from the start of the supply of the operating power to the occurrence of the specific trigger. It is possible to prevent a difference in required period. Therefore, when the supply of operating power to a plurality of gaming machines is started at the same time, the gaming machine in which the first processing is executed and the gaming machine in which the second processing is executed in the processing at the start of supply. It is possible to align the timing of occurrence of the specific trigger in. With the configuration of the above characteristic αf1, the predetermined trigger is periodically generated based on the specific trigger. Therefore, by aligning the occurrence timings of the specific triggers in the plurality of gaming machines, it is possible to align the reference of the occurrence timings of the predetermined triggers in the plurality of gaming machines.

Feature αf3. Whether the first process is executed or the second process is executed in the process at the start of supply has a configuration that does not affect the cycle in which the predetermined trigger occurs. The gaming machine according to the characteristic feature αf2.

According to the feature αf3, the gaming machine in which the first process is executed in the process at the start of supply and the gaming machine in which the second process is executed in the process at the start of supply have a predetermined opportunity based on the specific opportunity. The generated cycles can be the same cycle. By having the configuration of the above characteristic αf2, the operation is performed in the gaming machine in which the first processing is executed in the processing at the start of supply and in the gaming machine in which the second processing is executed in the processing at the start of supply. There is no difference in the time required from the start of power supply to the occurrence of a specific trigger. Therefore, by starting the supply of operating power to a plurality of gaming machines at the same time, the gaming machine in which the first processing is executed in the processing at the start of supply and the second processing in the processing at the start of supply are performed. The timing of occurrence of the specific trigger can be aligned with the executed gaming machine. In the configuration including the configuration of the above characteristic αf1, the predetermined effect is started based on the fact that the predetermined trigger is generated in the predetermined state, the generation timing of the specific trigger in the plurality of gaming machines, and By aligning the generation cycle of the predetermined triggers that regularly occur on the basis of the specific triggers, it is possible to align the timing at which the predetermined effect is started in a predetermined state in the plurality of gaming machines.

It has the configuration of the above characteristic αf2 and is required from the start of the supply start process to the completion thereof depending on whether the first process is executed or the second process is executed in the supply start process. The period varies. In this configuration, when the supply of operating power to a plurality of gaming machines is started at the same time, the gaming machine in which the first processing is executed in the processing at the start of supply and the second processing in the processing at the start of supply By enabling the predetermined effect to be started simultaneously with the game machine on which the game is executed, the game machine on which the first process is executed and the game machine on which the second process is executed are determined based on the start timing of the predetermined effect. It is possible to prevent it from being easily performed.

Features αf4. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (function of executing the process of step SB311 in the main CPU 63),
When a supply of operating power is started, a predetermined setting-related operation (ON operation of the setting key insertion part 68a for executing the set value updating process and pressing of the reset button 68c, or a process for confirming the setting is executed. Setting-related execution means (main CPU 63) that executes a predetermined setting-related process relating to the set value as the first process in the process at the start of supply based on the fact that the setting key insertion section 68a has been turned ON). Function for executing the setting value updating process in (2), a function for executing the setting confirmation process in the main CPU 63),
Equipped with
The gaming machine according to feature αf2 or αf3, wherein the second process is executed based on the fact that the predetermined setting-related operation is not performed when the supply of operating power is started. ..

According to the feature αf4, in the process at the start of supply, the predetermined setting-related process is executed based on the fact that the predetermined setting-related operation is performed when the supply of the operating power is started, and the predetermined setting-related operation is performed. The second processing is executed based on the fact that the above is not performed. By providing the configuration of the above characteristic αf2, the supply of operating power is started in the gaming machine in which the predetermined setting-related processing is executed in the processing at the start of supply and the gaming machine in which the second processing is executed. It is possible to prevent a difference from occurring in the period required from the occurrence of the event to the occurrence of the specific trigger. The above-mentioned characteristic αf1 is provided, and the predetermined trigger is generated on the basis of the specific trigger, and the predetermined effect is started based on the fact that the predetermined trigger is generated in the predetermined state. It is a configuration that is done. In the configuration, in the gaming machine in which the predetermined setting-related processing is executed in the processing at the start of supply and in the gaming machine in which the second processing is executed, a specific trigger occurs after the supply of the operating power is started. It is possible to prevent the gaming machine in which the predetermined setting-related processing is executed based on the start timing of the predetermined effect from being easily identified by preventing a difference in the period required until ..

Features αf5. A main control unit (MPU 62) having a start-time process execution unit (a function of executing the processes of steps SB101 to SB122 in the main CPU 63) that executes a process at the start of supply when the supply of operating power is started;
An effect control means (sound-light side MPU 352) having the predetermined trigger specifying means and the predetermined effect control means,
Equipped with
The gaming machine according to any one of features αf1 to αf4, wherein the specific trigger is generated when supply of operating power to the effect control unit is started.

According to the characteristic αf5, in the configuration in which the specific trigger is generated when the supply of the operating power to the effect control unit is started, the predetermined trigger for specifying whether or not the predetermined trigger that is regularly generated based on the specific trigger has occurred The opportunity specifying means is provided in the effect control means. This facilitates the grasp of the specific trigger by the predetermined trigger identifying means, and also facilitates the grasp of the predetermined trigger that occurs periodically on the basis of the specific trigger.

Features αf6. The main control means, when the processing at the start of supply is completed or when the processing is completed, predetermined start correspondence information (normal recovery command, clear recovery command, confirmation recovery command, or A predetermined transmission means (a function for executing the processing of steps SB113 and SB118 in the main CPU 63, a function of executing the processing of step SB207 in the main CPU 63, and a processing of step SB314 in the main CPU 63 for transmitting the update return command) Function to execute)
The effect control means, when receiving the predetermined start correspondence information, executes the information correspondence processing corresponding to the predetermined start correspondence information (in the 77th, 81st, and 88th embodiments, step SI504 to step in the sound-light side CPU 353). A function of executing the processing of SI517, a function of executing the processing of steps SI803 to SI816 in the 78th embodiment, and a function of executing the processing of steps SJ104 to SJ119 in the 79th and 80th embodiments). Cage,
The characteristic αf5 is characterized in that the period required from the start of the supply of the operating power to the reception of the predetermined start correspondence information by the effect control means does not affect the cycle in which the predetermined trigger occurs. Amusement machine.

According to the characteristic αf6, the cycle in which the predetermined trigger occurs is not affected by the period required from the start of the supply of the operating power until the performance control unit receives the predetermined start correspondence information. With the configuration of the above characteristic αf1, the predetermined effect is started based on the fact that the predetermined trigger has occurred in the predetermined state. Therefore, based on the cycle in which the predetermined effect is started in the predetermined state, the content of the processing performed in the main control means from the start of the supply of the operating power until the main control means transmits the predetermined start correspondence information. Can be prevented from being easily identified.

Features αf7. A start-time process executing means (a function of executing the processes of steps SB101 to SB122 in the main CPU 63) for executing the process at the start of supply of the operating power is started;
The gaming machine according to any one of features αf1 to αf6, wherein the predetermined state setting means sets the predetermined state based on the end of the process at the start of supply.

According to the characteristic αf7, the predetermined state is set based on the completion of the process at the start of supply. With the configuration of the above characteristic αf1, the predetermined effect is started when it is specified that a predetermined trigger has occurred in a predetermined state. Therefore, it is possible to prevent the predetermined effect from being started in the situation where the process at the start of supply is being executed. In addition, after the processing at the start of supply is completed, it is possible to start the predetermined effect based on the fact that the predetermined trigger is generated. Therefore, even if the end timing of the process at the start of supply is shifted in a plurality of gaming machines, if the timing of occurrence of the predetermined trigger is aligned in the plurality of game machines, after the processing at the start of supply is completed It is possible to align the start timing of the predetermined effect in.

Feature αf8. Specific effect control means (function for executing steps SI603 to SI614 in the sound-light side CPU 353) for executing a specific effect (game time effect, effect for opening/closing execution mode) which is executed with priority over the predetermined effect. ),
The predetermined state setting means,
A predetermined releasing means (a function of executing the processing of step SI611 in the sound-light side CPU 353) for releasing the predetermined state when a trigger for starting the specific effect occurs in the predetermined state;
Predetermined setting means for setting the predetermined state based on the end of the specific effect (in the 77th, 79th to 81st embodiments, the function of executing the process of step SI705 in the sound-light side CPU 353, the 78th embodiment). Then, the function of executing the processing of step SI905 in the sound-light side CPU 353),
The gaming machine according to any one of the features αf1 to αf7.

According to the feature αf8, the predetermined state is canceled based on the occurrence of the start of the specific effect, and the predetermined state is set based on the end of the specific effect. With the configuration of the above characteristic αf1, the predetermined effect is started when it is specified that a predetermined trigger has occurred in a predetermined state. Therefore, it is possible to prevent the predetermined effect from being started in the situation where the specific effect is being executed. In addition, after the specific effect is finished, it is possible to start the predetermined effect based on the fact that the predetermined trigger has been specified. For this reason, even if the end timing of the specific effect is shifted in a plurality of gaming machines, if the timing of occurrence of the predetermined trigger is aligned in the plurality of gaming machines, the start timing of the predetermined effect after the end of the specific effect Can be arranged.

Feature αf9. At least a changing unit that changes the timing at which the predetermined trigger first occurs (in the 79th embodiment, the function of executing the processing of steps SJ201 to SJ204 in the sound-light side CPU 353, in the 80th embodiment, in the sound-light side CPU 353). Any one of the characteristics αf1 to αf8 characterized by having a function of executing the processing of steps SJ301 to SJ304, and a function of executing the processing of step SK716 in the sound-light side CPU 353 in the 88th embodiment. The game machine described.

According to the feature αf9, it is possible to change at least the timing at which the predetermined trigger first occurs. Further, the above-mentioned characteristic αf1 is provided, and the predetermined effect is started based on the fact that a predetermined trigger is generated in a predetermined state. Therefore, when the supply of the operating power to the plurality of gaming machines is started at the same time, the timing of occurrence of the predetermined trigger is different in the plurality of gaming machines according to the variation mode of the timing at which the predetermined trigger first occurs. In addition to the timing, the start timing of the predetermined effect in the predetermined state can be different. By providing a fluctuating means and intentionally creating a situation in which the timing of occurrence of the predetermined trigger is shifted in a plurality of gaming machines, specific processing such as processing for making advantageous settings for the player based on the start timing of the predetermined effect It is possible to prevent the gaming machine on which the processing has been executed from being easily specified.

Feature αf10. The fluctuating means fluctuates the timing at which the predetermined trigger first occurs,
10. The gaming machine according to feature αf9, wherein the changing mode of the predetermined trigger by the changing unit does not affect the generation cycle of the predetermined trigger after the first generation timing of the predetermined trigger.

According to the characteristic αf10, the variation mode of the predetermined trigger by the changing unit does not affect the generation cycle of the predetermined trigger after the first generation timing of the predetermined trigger. In addition, the predetermined effect is started on the basis of the fact that the predetermined trigger is generated in the predetermined state, which is provided with the configuration of the characteristic αf1. Therefore, it is possible to prevent the variation mode of the predetermined trigger from being specified based on the cycle in which the predetermined effect is started after the first occurrence timing of the predetermined trigger.

In addition, when the supply of operating power to a plurality of gaming machines is started at the same time, some gaming machines in which the variation mode of the first occurrence timing of the predetermined trigger is the same among the plurality of gaming machines, It is possible to align the timing of occurrence of the predetermined trigger of. Further, it is possible to increase the possibility that a situation occurs in which the timing of occurrence of the predetermined trigger in some of the gaming machines and the timing of occurrence of the predetermined trigger in the remaining gaming machines are deviated. Since the predetermined effect is started based on the fact that the predetermined trigger has been identified in the predetermined state, the start of the predetermined effect on some gaming machines when the situation occurs. By aligning the timing, it is possible to give a certain sense of unity to the predetermined effect and increase the player's interest in the gaming machine. In addition, it is presumed that the advantageous settings for the player have been made to the remaining game machines whose start timings of the predetermined effects are different from those of the part of the game machines. It becomes possible to raise the interest of the player.

Feature αf11. Main control means (MPU 62) to which backup power for storing and holding information is supplied in a situation where supply of operating power is stopped;
Effect control means (sound-light side MPU 352) that has the changing means and is not supplied with backup power for storing and holding information in a situation where supply of operating power is stopped,
Equipped with
The main control means provides the effect control means with variation information (random number information for lottery in the 79th and 80th embodiments) for varying the timing at which the predetermined trigger first occurs. The gaming machine according to the characteristic αf9 or αf10.

According to the characteristic αf11, it is possible to adopt a configuration in which the main control unit stores and holds the fluctuation information in a situation where the supply of the operating power is stopped. Thereby, a predetermined trigger is first generated by using the fluctuation information stored in the main control unit at the time of the previous stop of the supply of the operating power, while the configuration for supplying the backup power to the effect control unit is not provided. It is possible to change the timing.

Feature αf12. The main control means,
A predetermined storage means (main side RAM 65) in which the fluctuation information is stored,
Predetermined initialization means (first RAM clear processing) for initializing the storage area to be initialized in the predetermined storage means when supply of operating power is started (step SB117 in the main CPU 63). Function to execute processing),
A non-predetermined storage means (transmission random number storage counter 556 in the 79th and 80th embodiments) excluded from the target of the predetermined initialization processing in the predetermined storage means;
Equipped with
When the supply of the operating power is started, the fluctuation information stored in the predetermined storage means is stored in the predetermined non-target storage means before the predetermined initialization processing is executed. The gaming machine according to the feature αf11.

According to the feature αf12, the fluctuation information is stored in the non-predetermined storage means before the predetermined initialization processing is executed, so that the predetermined storage means stores and holds the operating power in a situation where the supply of operating power is stopped. It is possible to avoid clearing the change information that has been used, and to provide the change information to the effect control unit.

Features αf13. The variation means executes variation lottery processing for determining a variation manner of the timing at which the predetermined trigger occurs (in the 79th embodiment, the processing of steps SJ201 to SJ203 in the sound-light side CPU 353 is performed. A function to execute the processing of steps SJ301 to SJ303 in the sound-light side CPU 353 in the 80th embodiment, and a function to execute the processing of SK716 in the sound-light side CPU 353 in the 88th embodiment). The gaming machine according to any one of the features αf9 to αf12.

According to the characteristic αf13, since the timing at which the predetermined trigger is generated is changed based on the lottery result of the variable lottery process, each variation mode of the timing at which the predetermined trigger is generated with the probability set in the design stage is generated. It becomes possible.

In addition, with respect to the configurations of the features αf1 to αf13, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1-. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, and features βA1 to βA. 4. Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αg group>
Features αg1. A predetermined effect (demonstration effect) based on the occurrence of a predetermined trigger (the value of the timer counter 554a for starting a demo reaches the maximum value in the 79th, 80th, and 88th embodiments) after the supply of operating power is started. A predetermined effect control means for starting (a function of executing the processing of step SI709 of the sound-light side CPU 353 in the 79th, 80th, and 88th embodiments),
A changing unit that changes the timing at which the predetermined trigger occurs after the supply of the operating power is started (in the 79th embodiment, the function of executing the processes of steps SJ201 to SJ204 in the sound-light side CPU 353, the 80th embodiment). A function of executing the processing of steps SJ301 to SJ304 in the sound-light side CPU 353, and a function of executing the processing of step SK716 in the sound-light side CPU 353 in the 88th embodiment).
A gaming machine characterized by being equipped with.

According to the feature αg1, it is possible to change the period required from the start of the supply of the operating power to the occurrence of the predetermined trigger, according to the change mode of the generation timing of the predetermined trigger by the changing unit. Therefore, when the supply of operating power to a plurality of gaming machines is started at the same time, the timing of occurrence of the prescribed triggers in the plurality of gaming machines is shifted according to the variation mode of the timing of occurrence of the prescribed triggers by the varying means. It is possible to cause the situation. Since the predetermined effect is started based on the occurrence of the predetermined trigger, it is possible to cause a situation in which the start timing of the predetermined effect is deviated in a plurality of gaming machines in which the supply of operating power is started at the same time. Becomes Accordingly, when an operation for confirming or changing the degree of advantage for the player is performed on some of the plurality of gaming machines for which the supply of operating power is started at the same time, a predetermined effect is produced. It is possible to reduce the possibility that some of the gaming machines on which the operation has been performed are likely to be identified based on the start timing.

Features αg2. A start-time process executing means (a function of executing the processes of steps SB101 to SB122 in the main CPU 63) for executing the process at the start of supply of the operating power is started;
When the first processing (setting value update processing, setting value confirmation processing) is executed in the processing at the start of supply and the second processing (processing of step SB113 in the main CPU 63, processing of step SB118 in the main CPU 63) When the process is performed, the period required from the start of the process at the start of supply to the completion of the process varies,
The changing means changes the timing at which the predetermined trigger occurs after the supply of the operating power is started, in addition to the change in the period required from the start to the completion of the processing at the start of the supply. The gaming machine according to the feature αg1.

According to the characteristic αg2, the period required from the start of the supply start process to the completion thereof varies depending on whether the first process is executed or the second process is executed in the supply start process. In such a configuration, it is possible to prevent the variation mode of the generation timing of the predetermined trigger by the variation unit from being influenced by the period. The above-mentioned characteristic αg1 is provided, and the predetermined effect is started based on the occurrence of the predetermined trigger after the start of the supply of the operating power. Therefore, it is possible to prevent the gaming machine in which the first processing is executed and the gaming machine in which the second processing is executed from being easily discriminated from each other based on the start timing of the predetermined effect. be able to.

Features αg3. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (function of executing the process of step SB311 in the main CPU 63),
When a supply of operating power is started, a predetermined setting-related operation (ON operation of the setting key insertion part 68a for executing the set value updating process and pressing of the reset button 68c, or a process for confirming the setting is executed. Setting-related execution means (main CPU 63) that executes a predetermined setting-related process relating to the set value as the first process in the process at the start of supply based on the fact that the setting key insertion section 68a has been turned ON). Function for executing the setting value updating process in (2), a function for executing the setting confirmation process in the main CPU 63),
Equipped with
The gaming machine according to feature αg2, wherein the second process is performed based on the fact that the predetermined setting-related operation is not performed when supply of operating power is started.

According to the characteristic αg3, in the process at the start of supply, the predetermined setting-related process is executed based on the fact that the predetermined setting-related operation is performed when the supply of the operating power is started, and the predetermined setting-related operation is performed. The second processing is executed based on the fact that the above is not performed. With the configuration of the characteristic αg2 described above, the process at the start of supply is started after the process at the start of supply is started depending on whether the predetermined setting-related process is executed or the second process is executed. In a configuration in which the period required for completion is varied, it is prevented that the variation mode of the timing of occurrence of the predetermined trigger by the variation means is affected by the period. In addition, the above-described characteristic αg1 is provided, and the predetermined effect is started based on the occurrence of a predetermined trigger after the start of the supply of the operating power. Therefore, it is possible to prevent the gaming machine in which the predetermined setting-related processing has been executed from being easily identified in the processing at the start of supply based on the start timing of the predetermined effect.

Features αg4. The predetermined trigger occurs regularly,
It is characterized in that it does not affect the cycle in which the predetermined trigger occurs, whether the first process is executed or the second process is executed in the process at the start of supply. The gaming machine described in the characteristics αg2 or αg3.

According to the feature αg4, the configuration of the feature αg1 is provided, and the predetermined effect is started based on the occurrence of the predetermined trigger after the start of the supply of the operating power. Therefore, if the configuration is such that the generation cycle of the predetermined trigger changes depending on whether the first process is executed or the second process is executed in the process at the start of supply, the predetermined effect is started. There is a possibility that the gaming machine in which the first processing is executed and the gaming machine in which the second processing is executed may be easily discriminated from each other based on the cycle. On the other hand, the configuration is such that the cycle in which the predetermined trigger occurs is not affected whether the first processing is executed or the second processing is executed in the processing at the start of supply. As a result, the game machine in which the first process is executed and the game in which the second process is executed in the process at the start of supply based on the cycle in which the predetermined effect is started while the predetermined effect is periodically started. It is possible to prevent the machine from being easily discriminated.

Features αg5. The predetermined trigger occurs regularly,
The fluctuating means fluctuates the timing at which the predetermined trigger first occurs,
The gaming machine according to any one of features αg1 to αg4, wherein the generation cycle of the predetermined trigger after the first generation timing of the predetermined trigger does not change.

According to the characteristic αg5, in the configuration including the configuration of the characteristic αg1 and in which the predetermined effect is started based on the occurrence of the predetermined trigger after the supply of the operating power is started, the predetermined trigger after the first generation timing of the predetermined trigger is generated. Since the generation cycle of does not change, it is possible to prevent the variation mode of the timing at which the predetermined trigger first occurs based on the cycle at which the predetermined effect starts after the first generation timing of the predetermined trigger. can do.

In addition, when the supply of operating power to a plurality of gaming machines is started at the same time, some gaming machines in which the variation mode of the first occurrence timing of the predetermined trigger is the same among the plurality of gaming machines, It is possible to align the timing of occurrence of the predetermined trigger of. Further, it is possible to increase the possibility that a situation occurs in which the timing of occurrence of the predetermined trigger in some of the gaming machines and the timing of occurrence of the predetermined trigger in the remaining gaming machines are deviated. Since the predetermined effect is started based on the occurrence of the predetermined trigger after the supply of the operating power is started, when the situation occurs, the start timing of the predetermined effect should be aligned in some gaming machines. As a result, it is possible to give the predetermined effect a sense of unity and increase the player's interest in the gaming machine. In addition, it is presumed that the advantageous settings for the player have been made to the remaining game machines whose start timings of the predetermined effects are different from those of the part of the game machines. It becomes possible to raise the interest of the player.

Features αg6. The fluctuating means executes a fluctuating lottery process for executing a fluctuating lottery process for determining a fluctuating mode of the timing at which the predetermined trigger first occurs (in the 79th embodiment, the processes of steps SJ201 to SJ203 in the sound-light side CPU 353). The function of executing steps SJ301 to SJ303 in the sound-light side CPU 353 in the 80th embodiment, and the function of executing SK716 in the sound-light side CPU 353 in the 88th embodiment). The gaming machine according to feature αg5.

According to the characteristic α6, since the timing at which the predetermined trigger first occurs is changed based on the lottery result of the variable lottery process, the variation mode of the first occurrence timing of the predetermined trigger with the probability set in the design stage. Can be generated.

Features αg7. Main control means (MPU 62) to which backup power for storing and holding information is supplied in a situation where supply of operating power is stopped;
Effect control means (sound-light side MPU 352) that has the changing means and is not supplied with backup power for storing and holding information in a situation where supply of operating power is stopped,
Equipped with
The main control means provides the effect control means with variation information (random number information for lottery in the 79th and 80th embodiments) for varying the timing at which the predetermined trigger first occurs. The gaming machine according to any one of features αg1 to αg6.

According to the characteristic αg7, it is possible to adopt a configuration in which the fluctuation information is stored and held in the main control means even when the supply of the operating power is stopped. Therefore, it is possible to change the timing at which the predetermined trigger first occurs by using the changing information stored in the main control unit when the supply of the operating power was stopped last time.

Features αg8. The main control means,
A predetermined storage means (main side RAM 65) in which the fluctuation information is stored,
Predetermined initialization means (first RAM clear processing) for initializing the storage area to be initialized in the predetermined storage means when supply of operating power is started (step SB117 in the main CPU 63). Function to execute processing),
A non-predetermined storage means (transmission random number storage counter 556 in the 79th and 80th embodiments) excluded from the target of the predetermined initialization processing in the predetermined storage means;
Equipped with
When the supply of the operating power is started, the fluctuation information stored in the predetermined storage means is stored in the predetermined non-target storage means before the predetermined initialization processing is executed. The gaming machine according to the feature αg7.

According to the feature αg8, the fluctuation information is stored in the non-predetermined storage means before the predetermined initialization process is executed, so that the predetermined storage means stores and holds the operating power in a situation where the supply of the operating power is stopped. It is possible to avoid clearing the change information that has been used, and to provide the change information to the effect control means.

In addition, with respect to the configuration of the features αg1 to αg8, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αh group>
Features αh1. Start-time process execution means (a function of executing the processes of steps SB101 to SB122 in the main CPU 63) that executes the process at the start of supply when the supply of the operating power is started;
Predetermined periodically generated based on a specific trigger (start of updating the demo start timer counter 554a after the sound/light side RAM clear processing in the 79th, 80th, and 88th embodiments) that occurs after the supply of operating power is started. Predetermined trigger specifying means (79th, 80th, 80th, 80th, 88th, 88th, 88th, 88th, 88th, 88th Embodiments) which determines whether the value of the timer counter 554a for starting a demo reaches the maximum value. 88, the function of executing the processing of steps SI707 and SI712 of the sound-light-side CPU 353).
A predetermined effect control means (79th) for starting a predetermined effect (demo effect) based on the fact that the predetermined trigger specifying means specifies that the predetermined trigger has occurred after the processing at the start of supply is completed. , A function of executing the processing of step SI709 of the sound-light side CPU 353 in the 80th and 88th embodiments),
Equipped with
When the first processing (setting value update processing, setting value confirmation processing) is executed in the processing at the start of supply and the second processing (processing of step SB113 in the main CPU 63, processing of step SB118 in the main CPU 63) When the process is performed, the period required from the start of the process at the start of supply to the completion of the process varies,
This gaming machine, at least the varying means for varying the timing at which the predetermined trigger first occurs (in the 79th embodiment, a function of executing the processing of steps SJ201 to SJ204 in the sound-light side CPU 353, in the 80th embodiment A game machine having a function of executing the processing of steps SJ301 to SJ304 in the sound-light side CPU 353, and a function of executing the processing of step SK716 in the sound-light side CPU 353 in the 88th embodiment.

According to the feature αh1, it is possible to change at least the timing at which the predetermined trigger first occurs, and the predetermined effect is started based on the fact that the predetermined trigger has been specified. For this reason, when the supply of the operating power to the plurality of gaming machines is started at the same time, the timing of occurrence of the predetermined trigger is different in the plurality of gaming machines according to the variation mode of the timing at which the predetermined trigger first occurs. In addition to the timing, the start timing of the predetermined effect can be different timing. In the configuration in which the period required from the start of the process at the start of supply to the completion of the process varies depending on whether the first process is executed or the second process is executed in the process at the start of supply, In this gaming machine, it is possible to intentionally cause a situation in which the timing of occurrence of the predetermined trigger is deviated. This prevents the gaming machine in which the first processing is executed and the gaming machine in which the second processing is executed from being easily discriminated from each other based on the start timing of the predetermined effect. be able to. Further, since the predetermined effect is started based on the occurrence of the predetermined trigger after the process at the start of supply is completed, it is possible to prevent the predetermined effect from being started before the completion of the process at the start of supply. be able to.

Features αh2. Regardless of whether the first process is executed or the second process is executed in the process at the start of supply, from when the supply of the operating power is started to when the specific trigger is generated. The gaming machine according to feature αh1, which has a configuration that does not affect a required period.

According to the characteristic αh2, in a case where the first process is executed and a case where the second process is executed in the process at the start of supply, from the start of the supply of the operating power to the occurrence of the specific trigger. It is possible to prevent a difference in required period. Therefore, when the supply of operating power to a plurality of gaming machines is started at the same time, the gaming machine in which the first processing is executed and the gaming machine in which the second processing is executed in the processing at the start of supply. It is possible to align the timing of occurrence of the specific trigger in. With the configuration of the above characteristic αh1, the predetermined trigger is generated periodically on the basis of the specific trigger, and the predetermined effect is specified to have occurred after the completion of the process at the start of supply. It will be started based on that. Therefore, by aligning the reference of the timing of occurrence of the predetermined trigger in the plurality of gaming machines, the gaming machine in which the first processing is executed and the second processing are executed in the processing at the start of supply based on the start timing of the predetermined effect. It is possible to prevent the game machine from being easily discriminated.

Features αh3. Whether the first process is executed or the second process is executed in the process at the start of supply has a configuration that does not affect the cycle in which the predetermined trigger occurs. The gaming machine described in Characteristic αh2.

According to the characteristic αh3, the gaming machine in which the first processing is executed in the processing at the start of supply and the gaming machine in which the second processing is executed in the processing at the start of supply have a predetermined opportunity based on the specific opportunity. The cycles that occur can be the same cycle. Further, with the configuration of the above characteristic αh1, the predetermined effect is started based on the fact that the predetermined trigger has occurred after the completion of the process at the start of supply. Therefore, it becomes easy to distinguish the gaming machine in which the first processing is executed and the gaming machine in which the second processing is executed in the processing at the start of supply based on the cycle in which the predetermined effect is started. Can be prevented.

Features αh4. Setting means for setting a setting value to be used from a plurality of setting values corresponding to the player's advantage (function of executing the process of step SB311 in the main CPU 63),
When a supply of operating power is started, a predetermined setting-related operation (ON operation of the setting key insertion part 68a for executing the set value updating process and pressing of the reset button 68c, or a process for confirming the setting is executed. Setting-related execution means (main CPU 63) that executes a predetermined setting-related process relating to the set value as the first process in the process at the start of supply based on the fact that the setting key insertion section 68a has been turned ON). Function for executing the setting value updating process in (2), a function for executing the setting confirmation process in the main CPU 63),
Equipped with
The gaming machine according to feature αh2 or αh3, wherein the second process is performed based on the fact that the predetermined setting-related operation is not performed when supply of operating power is started. ..

According to the characteristic αh4, in the process at the start of supply, the predetermined setting-related process is executed based on the predetermined setting-related operation being performed when the supply of the operating power is started, and the predetermined setting-related operation is performed. The second processing is executed based on the fact that the above is not performed. By providing the configuration of the characteristic αh2, there is a difference in the timing of occurrence of the specific trigger between when the predetermined setting-related process is executed in the process at the start of supply and when the second process is executed. It is prevented from occurring. With the configuration of the above characteristic αh1, the configuration is such that a predetermined trigger is generated periodically based on the specific trigger, and it is specified that the predetermined trigger is generated after the process at the start of supply is completed. Based on this, the predetermined effect is started. In the configuration, it is possible to prevent a difference in the generation timing of the specific trigger between when the predetermined setting-related process is executed and when the second process is executed in the process at the start of supply. As a result, it is possible to prevent the gaming machine on which the predetermined setting-related processing has been executed from being easily identified based on the start timing of the predetermined effect.

Features αh5. A main control means (MPU 62) having the start-time processing execution means,
An effect control means (sound-light side MPU 352) having the predetermined trigger specifying means and the predetermined effect control means,
Equipped with
The gaming machine according to any one of features αh1 to αh4, wherein the specific trigger is generated when supply of operating power to the effect control unit is started.

According to the characteristic αh5, in the configuration in which the specific trigger is generated when the supply of the operating power to the effect control unit is started, the predetermined trigger for specifying whether or not the predetermined trigger that regularly occurs on the basis of the specific trigger has occurred The opportunity specifying means is provided in the effect control means. This facilitates the grasp of the specific trigger by the predetermined trigger identifying means, and also facilitates the grasp of the predetermined trigger that occurs periodically on the basis of the specific trigger.

Features αh6. The main control means, when the processing at the start of supply is completed or when the processing is completed, predetermined start correspondence information (normal recovery command, clear recovery command, confirmation recovery command, or A predetermined transmission means (a function for executing the processing of steps SB113 and SB118 in the main CPU 63, a function of executing the processing of step SB207 in the main CPU 63, and a processing of step SB314 in the main CPU 63 for transmitting the update return command) Function to execute)
The said effect control means, when the said predetermined start corresponding information is received, the information corresponding means which performs the information corresponding process corresponding to it (in 79th and 80th embodiment, the function which performs the process of step SJ104-step SJ119, The 88th embodiment has a function of executing the processing of steps SI504 to SI517 in the sound-light side CPU 353).
The characteristic αh5 is characterized in that the period required from the start of the supply of operating power to the reception of the predetermined start correspondence information by the effect control means does not affect the cycle in which the predetermined trigger occurs. Amusement machine.

According to the characteristic αh6, the cycle in which the predetermined trigger occurs is not influenced by the period required from the start of the supply of the operating power until the performance control unit receives the predetermined start correspondence information. In addition, the predetermined effect is started based on the fact that the constitution of the characteristic αh1 is provided and it is specified that the predetermined trigger has occurred after the processing at the start of supply is completed. Therefore, it is easy to specify the content of the processing performed in the main control means from the start of the supply of the operating power until the main control means transmits the predetermined start correspondence information, based on the cycle in which the predetermined effect is started. Can be prevented.

Features αh7. Specific effect control means (function for executing steps SI603 to SI614 in the sound-light side CPU 353) for executing a specific effect (game time effect, effect for opening/closing execution mode) which is executed with priority over the predetermined effect. ),
The predetermined effect control means starts the predetermined effect based on the fact that the predetermined trigger specifying means specifies that the predetermined trigger has occurred after the specific effect ends. The gaming machine according to any one of αh1 to αh6.

According to the feature αh7, it is possible to prevent the predetermined effect from being started in the situation where the specific effect is being executed. Further, after the specific effect is finished, the predetermined effect is started based on the fact that the predetermined trigger is generated. For this reason, even if the end timing of the specific effect is shifted in a plurality of gaming machines, if the timing of occurrence of the predetermined trigger is aligned in the plurality of gaming machines, the start timing of the predetermined effect after the end of the specific effect Can be arranged.

Features αh8. The fluctuating means fluctuates the timing at which the predetermined trigger first occurs,
The game according to any one of features αh1 to α7, characterized in that the changing mode of the predetermined trigger by the changing unit does not affect the generation cycle of the predetermined trigger after the first generation timing of the predetermined trigger. Machine.

According to the characteristic αh8, the variation mode of the predetermined trigger by the changing unit does not affect the generation cycle of the predetermined trigger after the first generation timing of the predetermined trigger. Further, the predetermined effect is started on the basis of the fact that it is specified that the predetermined trigger is generated after the processing at the start of supply is completed, having the configuration of the characteristic αh1. Therefore, it is possible to prevent the variation mode of the predetermined trigger from being specified based on the cycle in which the predetermined effect is started after the first occurrence timing of the predetermined trigger.

In addition, when the supply of operating power to a plurality of gaming machines is started at the same time, some gaming machines in which the variation mode of the first occurrence timing of the predetermined trigger is the same among the plurality of gaming machines, It is possible to align the timing of occurrence of the predetermined trigger of. Further, it is possible to increase the possibility that a situation occurs in which the timing of occurrence of the predetermined trigger in some of the gaming machines and the timing of occurrence of the predetermined trigger in the remaining gaming machines are deviated. Since the predetermined effect is started based on the fact that the predetermined trigger has been identified after the processing at the start of supply is completed, when the situation occurs, a part of the game is played. By aligning the start timings of the predetermined effects on the machine, it is possible to give the predetermined effect a sense of unity and increase the player's interest in the game machine. In addition, it is presumed that the advantageous settings for the player have been made to the remaining game machines whose start timings of the predetermined effects are different from those of the part of the game machines. It becomes possible to raise the interest of the player.

Features αh9. Main control means (MPU 62) to which backup power for storing and holding information is supplied in a situation where supply of operating power is stopped;
Effect control means (sound-light side MPU 352) that has the changing means and is not supplied with backup power for storing and holding information in a situation where supply of operating power is stopped,
Equipped with
The main control means provides the effect control means with variation information (random number information for lottery in the 79th and 80th embodiments) for varying the timing at which the predetermined trigger first occurs. The gaming machine according to any one of features αh1 to αh8.

According to the characteristic αh9, it is possible to adopt a configuration in which the fluctuation information is stored and held in the main control means even when the supply of the operating power is stopped. Therefore, it is possible to change the timing at which the predetermined trigger first occurs by using the changing information stored in the main control unit when the supply of the operating power was stopped last time.

Features αh10. The main control means,
A predetermined storage means (main side RAM 65) in which the fluctuation information is stored,
Predetermined initialization means (first RAM clear processing) for initializing the storage area to be initialized in the predetermined storage means when supply of operating power is started (step SB117 in the main CPU 63). Function to execute processing),
A non-predetermined storage means (transmission random number storage counter 556 in the 79th and 80th embodiments) excluded from the target of the predetermined initialization processing in the predetermined storage means;
Equipped with
When the supply of the operating power is started, the fluctuation information stored in the predetermined storage means is stored in the predetermined non-target storage means before the predetermined initialization processing is executed. The gaming machine according to the feature αh9.

According to the characteristic αh10, by storing the fluctuation information in the non-predetermined storage means before the predetermined initialization processing is executed, it is stored and held in the predetermined storage means in a situation where the supply of operating power is stopped. It is possible to avoid clearing the change information that has been used, and to provide the change information to the effect control means.

Features αh11. The variation means executes variation lottery processing for determining the variation mode of the timing at which the predetermined trigger occurs (in the 79th embodiment, the processing of steps SJ201 to SJ203 in the sound-light side CPU 353 is performed. A function to execute the processing of steps SJ301 to SJ303 in the sound-light side CPU 353 in the 80th embodiment, and a function to execute the processing of SK716 in the sound-light side CPU 353 in the 88th embodiment). The gaming machine according to any one of the features αh1 to αh10.

According to the characteristic αh11, since the timing at which the predetermined trigger is generated is changed based on the lottery result of the variable lottery process, each variation mode of the timing at which the predetermined trigger is generated with the probability set in the design stage is generated. It becomes possible.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features αg1 to αh11. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, and features βA1 to βA. 4. Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the inventions related to the characteristic αe group, the characteristic αf group, the characteristic αg group, and the characteristic αh group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, the pachinko machine is equipped with a dish storage section for storing the game balls given to the player on the front side of the game machine, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, it is necessary to suitably control the execution of the effect, and there is still room for improvement in this respect.

<Characteristic αi group>
Features αi1. When a predetermined event occurs due to the execution of a game, history storage execution means (normal entrance management processing in the main CPU 63) for storing history information of the game corresponding to it in the history storage means (normal counter area 231) Function to execute)
Information derivation means (function of executing the process of step S8601 in the main CPU 63) for deriving mode information (base value) corresponding to the result of the game using the history information stored in the history storage means,
Aspect-related information (representative value data in the 82nd embodiment, processing representative value data in the 83rd embodiment, which enables the presence/absence of abnormality of the aspect information or the aspect information derived by the information deriving unit to be grasped 84th embodiment, base value abnormal signal, 85th embodiment upper base value abnormal signal and lower base value abnormal signal, 86th embodiment upper base value abnormal signal, lower first base value abnormal signal, Lower second base value abnormal signal, common base value abnormal signal, upper base value abnormal signal and lower base value abnormal signal in the 87th embodiment) is output to the outside of the gaming machine. In the embodiment, the function of executing the process of step SJ405 in the main CPU 63, in the 83rd embodiment, the function of executing the process of step SJ507 in the main CPU 63, and in the 84th embodiment, the process of step SJ611 in the main CPU 63. Function to be executed, function to execute the process of step SJ810 in the main CPU 63, function to execute the processes of step SK202 and step SK205 in the main CPU 63 in the 85th embodiment, step in the main CPU 63 in the 86th embodiment SK502, a function of executing the processes of steps SK505 and SK508, a function of executing the processes of steps SK602, SK604 and SK607 in the main CPU 63 in the 87th embodiment).
A gaming machine characterized by being equipped with.

According to the characteristic αi1, when the predetermined event occurs, the history information corresponding to the predetermined event is stored in the history storage means. By storing the history information in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, the mode information corresponding to the result of the game is derived using the history information stored in the history storage means, and the derived mode information is stored in the mode information storage means. As a result, it becomes possible to store and hold information for managing the number of occurrences or the frequency of occurrence of a predetermined event in the gaming machine, and it is preferable to manage the frequency of occurrence of the predetermined event by using this managed information. It becomes possible to do it.

Further, the aspect information or the aspect-related information is externally output from the gaming machine to an external device such as a hall computer. Therefore, at least the presence/absence of abnormality in the aspect information can be grasped in the external device. This makes it possible to omit the work of the game hall manager who goes to the place where the gaming machine is installed and checks the mode information. In addition, when a plurality of gaming machines are installed in the gaming hall, it is possible to collectively grasp the aspect information or the aspect-related information of the plurality of gaming machines in the external device. Thereby, it is possible to collectively grasp at least whether or not there is an abnormality in the aspect information for the plurality of gaming machines. Therefore, it is possible to suitably manage the occurrence frequency of the predetermined event, while reducing the monitoring load on the manager of the game hall.

Features αi2. The aspect information derived by the information deriving unit is numerical information having a digit number of 2 or more,
The predetermined information output means is configured to externally output the aspect-related information,
The gaming machine according to feature αi1, wherein the aspect-related information is information corresponding to a numerical value including a part of digits of the aspect information and a predetermined digit (first decimal place).

According to the feature αi2, the data amount of the aspect-related information output to the outside of the gaming machine can be reduced as compared with the configuration in which the information that allows the entire aspect information to be grasped is output to the outside of the gaming machine. .. This makes it possible to reduce the data capacity of the storage area for storing the aspect-related information in order to output the aspect-related information to the outside of the gaming machine. Further, the aspect-related information can be externally output to an external device such as a hall computer having a small storage capacity for storing information that enables the presence/absence of abnormality of the aspect information to be grasped. Further, in the configuration in which the aspect-related information is externally output by parallel communication, the number of signal lines for performing the external output can be reduced.

Features αi3. The aspect-related information is the numerical value itself of the predetermined digit in the aspect information (processing representative value data in 2-bit units in the 83rd embodiment) or information corresponding to the numerical value of the predetermined digit (the 83rd embodiment). The processing representative value data in units of 2 bits) in the gaming machine described in the feature αi2.

According to the feature αi3, when the numerical value of a predetermined digit in the aspect information is externally output, the presence or absence of an abnormality in the aspect information and the degree of the abnormality can be grasped by the external device, and the predetermined value in the aspect information can be obtained. When the information corresponding to the numerical value of the digit is output to the outside, the presence or absence of abnormality in the aspect information can be grasped by the external device.

Features αi4. The predetermined information output means, when the mode information is included in a predetermined numerical value range (base abnormal range (0 to 0.29) in the 83rd embodiment), corresponds to the mode information as the mode related information. (Processing representative value data of "0" to "2" in the 83rd embodiment) is externally output, and when the aspect information is not included in the predetermined numerical value range, the aspect information is the aspect related information. The gaming machine described in the feature αi2 or αi3, which is characterized in that information corresponding to being not included in the predetermined numerical value range (processing representative value data of “3” in the 83rd embodiment) is externally output.

According to the characteristic αi4, when the aspect information is included in the predetermined numerical value range, the information corresponding to the aspect information is externally output to the external device such as the hall computer. Therefore, when the aspect information is included in the predetermined numerical value range, the details of the aspect information can be grasped. As a result, not only the presence/absence of abnormality in the aspect information but also the degree of abnormality can be grasped. On the other hand, when the aspect information is not included in the predetermined numerical value range, information corresponding to the aspect information being not included in the predetermined numerical value range is externally output to the external device. If the information corresponding to the aspect information is externally output even when the aspect information is not included in the predetermined numerical value range, the data amount of the aspect-related information externally output from the gaming machine to the external device increases. On the other hand, when the aspect information is not included in the predetermined numerical value range, the information corresponding to the fact that the aspect information is not included in the predetermined numerical value range is externally output. It is possible to grasp that the aspect information is not included in the predetermined numerical range in the external device while reducing the data amount of the aspect-related information to be output to the outside.

Features αi5. Abnormality determining means for determining whether or not the aspect information is abnormal (in the 84th embodiment, a function of executing the processing of steps SJ605 and SJ606 in the main CPU 63, in the 85th and 87th embodiments, the main side). A function of executing the processing of steps SK102 and SK105 in the CPU 63, and a function of executing the processing of steps SK402, SK405 and SK408 in the 86th embodiment).
The predetermined information output means includes information corresponding to the determination result by the abnormality determination means (base value abnormality signal in the 84th embodiment, upper base value abnormality signal and lower base value abnormality signal in the 85th embodiment, In the 86th embodiment, the upper base value abnormality signal, the lower first base value abnormality signal and the lower second base value abnormality signal, and in the 87th embodiment, the common base value abnormality signal, the upper base value abnormality signal and the lower base value. A value abnormal signal) is externally output as the aspect-related information, The gaming machine according to any one of the features αi1 to αi4.

According to the feature αi5, it is unnecessary to set information that enables the normal range of the aspect information to be grasped in an external device such as a hall computer that receives the aspect-related information from the gaming machine, and the aspect information of the external device can be stored in the external device. It is possible to grasp the presence or absence of an abnormality.

Features αi6. Reference value information (a threshold value table 566 in the 84th to 85th and 87th embodiments, a threshold value table 573 in the 86th embodiment) that enables grasping a predetermined reference range (base normal range) of the aspect information is stored in advance. Provided predetermined information storage means (main side ROM 64),
The abnormality determining means determines whether the aspect information is within the predetermined reference range by using the reference value information, and when the aspect information is not within the predetermined reference range, the aspect information is The gaming machine according to feature αi5, which is characterized as being determined to be abnormal.

According to the feature αi6, it is possible to determine whether or not there is an abnormality in the aspect information based on the reference value information stored in advance in the predetermined information storage means. With the configuration of the above characteristic αi5, information corresponding to the determination result by the abnormality determination means is externally output from the gaming machine to an external device such as a hall computer. For this reason, it is possible to grasp the presence/absence of abnormality of the aspect information in the external device, while it is not necessary to set the predetermined reference range of the aspect information in the external device that receives the information.

Features αi7. A predetermined threshold value (upper threshold value in the 84th to 87th embodiments) indicating an upper limit of the predetermined reference range is set in the reference value information,
The gaming machine according to feature αi6, wherein the abnormality determination means determines that the aspect information is abnormal when the aspect information exceeds the predetermined threshold value.

According to the feature αi7, it is possible to determine based on the reference value information stored in advance whether or not the mode information is in an abnormal state in which it exceeds the predetermined threshold value. With the configuration of the above characteristic αi5, information corresponding to the determination result by the abnormality determination means is externally output from the gaming machine to an external device such as a hall computer. Therefore, it is possible to grasp whether or not the external device receiving the information is in an abnormal state in which the external mode information exceeds the predetermined threshold value, while it is unnecessary to set the predetermined reference range of the external information. can do.

Features αi8. A specific threshold value (a lower threshold value in the 84th to 85th and 87th embodiments, a lower first threshold value in the 86th embodiment) indicating the lower limit of the predetermined reference range is set in the reference value information. ,
The gaming machine according to feature αi6 or αi7, wherein the abnormality determination means determines that the aspect information is abnormal when the aspect information is below the specific threshold.

According to the feature αi8, it is possible to determine whether or not the mode information is in an abnormal state in which it is below the specific threshold value, based on the reference value information stored in advance. With the configuration of the above characteristic αi5, information corresponding to the determination result by the abnormality determination means is externally output from the gaming machine to an external device such as a hall computer. Therefore, it is possible to grasp whether or not the external device receiving the information is in an abnormal state in which the external mode information is below a specific threshold value, while it is not necessary to set the predetermined reference range of the external information. can do.

Features αi9. The reference value information includes a predetermined threshold value indicating the upper limit of the predetermined reference range (upper threshold value in the 85th to 87th embodiments) and a specific threshold value indicating the lower limit of the predetermined reference range (85th and 87th implementations). Lower threshold in the embodiment, lower first threshold in the 86th embodiment),
The predetermined information output means,
When the abnormality determination unit determines that the aspect information exceeds the predetermined threshold value, the first predetermined abnormality information indicating that the aspect information exceeds the predetermined threshold value as the aspect-related information (upper base First abnormality information output means for externally outputting a value abnormality signal (function of executing the process of step SK202 in the main CPU 63 in the 85th embodiment, executing the process of step S502 in the main CPU 63 in the 86th embodiment) Function for executing the process of step SK604 in the main CPU 63 in the 87th embodiment).
When the abnormality determining unit determines that the aspect information is below the specific threshold, the second predetermined abnormality information (85th) indicating that the aspect information is below the specific threshold as the aspect-related information. , The lower base value abnormality signal in the 87th embodiment, and the lower first base value abnormality signal in the 86th embodiment), which is externally output in a manner distinguishable from the first predetermined abnormality information. Output means (a function of executing the process of step SK205 in the main CPU 63 in the 85th embodiment, a function of executing the process of step SK505 in the main CPU 63 in the 86th embodiment, a main CPU 63 in the 87th embodiment Function for executing the processing of step SK607 in),
The gaming machine according to any one of the features αi6 to αi8.

According to the characteristic αi9, in the external device such as the hall computer that receives the aspect-related information from the gaming machine, the aspect information is in an abnormal state in which it exceeds a predetermined threshold, and the aspect information is in an abnormal state in which it falls below a specific threshold. Can be grasped in a form that can be identified. With this, the state of the aspect information with respect to the predetermined reference range can be grasped in detail in the external device. In addition, it is possible to prompt the manager of the game hall to take measures according to the state of the aspect information.

Feature αi10. The reference value information includes a predetermined threshold value indicating the upper limit of the predetermined reference range (upper threshold value in the 86th embodiment) and a specific threshold value indicating the lower limit of the predetermined reference range (lower first value in the 86th embodiment). Threshold value) and a special threshold value (lower second threshold value in the 86th embodiment) smaller than the specific threshold value are set,
The predetermined information output means indicates that the aspect information is below the special threshold as the aspect related information when the abnormality determining means determines that the aspect information is below the special threshold. A third abnormality information output unit (function of executing the process of step SK508 of the main CPU 63 in the 86th embodiment) that outputs 3 predetermined abnormality information (lower second base value abnormality signal in the 86th embodiment). The gaming machine according to any one of the features αi6 to αi9, which is characterized by being provided.

According to the feature αi10, an external device such as a hall computer that receives the aspect-related information from the gaming machine can recognize that the aspect information is in an abnormal state below a special threshold. Thereby, in the external device, it is possible to grasp that the mode information is significantly below the lower limit of the predetermined reference range, and it is possible to prompt the manager of the gaming hall to take a prompt action.

Feature αi11. The reference value information includes a predetermined threshold value indicating the upper limit of the predetermined reference range (upper threshold value in the 87th embodiment) and a specific threshold value indicating the lower limit of the predetermined reference range (lower threshold value in the 87th embodiment). And are set,
The predetermined information output means,
When the abnormality determination unit determines that the aspect information exceeds the predetermined threshold value, the first predetermined abnormality information indicating that the aspect information exceeds the predetermined threshold value as the aspect-related information (upper base First abnormality information output means (a function for executing the process of step SK604 of the main CPU 63 in the 87th embodiment) for externally outputting a value abnormality signal),
When the abnormality determining unit determines that the aspect information is below the specific threshold, the second predetermined abnormality information (lower side) indicating that the aspect information is below the specific threshold as the aspect-related information. Second abnormality information output means (a function of executing the process of step SK607 of the main CPU 63 in the 87th embodiment) that externally outputs the base value abnormality signal) in a manner distinguishable from the first predetermined abnormality information;
Common in both cases where the abnormality determination means determines that the aspect information is above the predetermined threshold value, and when the abnormality determination means determines that the aspect information is below the specific threshold value. Then, the common abnormality information output means (in the 87th embodiment) that externally outputs the common predetermined abnormality information (common base value abnormality signal) indicating that the aspect information does not fall within the predetermined reference range as the aspect-related information. A function of executing the process of step SK602 of the main CPU 63),
The gaming machine according to any one of the features αi6 to αi10.

According to the feature αi11, as the connection mode between the gaming machine and the external device such as the hall computer, the external mode receives only the common predetermined abnormal information, and the first predetermined abnormal information and the second predetermined abnormal information are received. The connection mode to be performed can be selected. When the connection mode in which the external device receives only the common predetermined abnormality information is selected, it can be grasped that the mode information is not within the predetermined reference range. In addition, when the connection mode that causes the external device to receive the first predetermined abnormality information and the second predetermined abnormality information is selected, the state information is above the predetermined threshold and the state information is below the specific threshold. And can be grasped in an identifiable manner.

Features αi12. A latest storage area (current area 311) for storing the latest aspect information derived by the information deriving means;
A past storage area (first to third history areas 312 to 314) that stores the aspect information derived by the information deriving unit before the aspect information stored in the latest storage area,
Equipped with
The abnormality determination means determines whether or not the aspect information stored in the past storage area is abnormal based on the occurrence of a predetermined determination trigger (mainly in the 84th embodiment. The side CPU 63 has a function of executing the processing of steps SJ801 to SJ809, and in the 85th to 87th embodiments, the main CPU 63 has a function of executing the processing of steps SK301 to SK307).
The predetermined information output means is information corresponding to the determination result by the past abnormality determination means (base value abnormality signal in the 84th embodiment, upper base value abnormality signal and lower base value abnormality signal in the 85th embodiment, In the 86th embodiment, the upper base value abnormality signal, the lower first base value abnormality signal and the lower second base value abnormality signal, and in the 87th embodiment, the common base value abnormality signal, the upper base value abnormality signal and the lower side Past abnormality information output means for outputting the base value abnormality signal) to the outside of the gaming machine as the aspect-related information (in the 84th embodiment, a function of executing the process of step SJ810 in the main CPU 63, the 85th to 87th implementations). The game machine according to any one of the features αi5 to αi11, which has a function of executing the process of step SK308 in the main CPU 63 in the form.

According to the characteristic αi12, since the latest aspect information and the past aspect information derived before that are stored, the occurrence frequency of the predetermined event is grasped not only in the latest but also in the past. It becomes possible. Further, since the information corresponding to the determination result as to whether the aspect information stored in the past storage area is abnormal is externally output to the external device such as the hall computer, the abnormality of the aspect information has occurred in the past. It is possible to grasp that. As a result, it is possible to reduce the possibility that an abnormality in the aspect information will be overlooked.

Features αi13. The gaming machine according to feature αi12, wherein the predetermined determination trigger is that supply of operating power is started.

According to the characteristic αi13, by confirming whether or not the predetermined abnormality information is output to the outside of the gaming machine at the start of the supply of the operating power, it is possible to grasp whether or not the abnormality of the mode information has occurred in the past. You can As a result, it is possible to reduce the possibility that an abnormality in the aspect information will be overlooked.

Features αi14. The predetermined information output means is based on the occurrence of a periodically generated output trigger (the value of the base value timer counter in the specific control work area 221 becomes “0”) or the aspect information or the The gaming machine according to any one of the features αi1 to αi13, wherein aspect-related information is output to the outside of the gaming machine.

According to the feature αi14, while suppressing the frequency of aspect information or aspect-related information being externally output from the gaming machine to an external device such as a hall computer, it is possible to periodically determine whether or not the aspect information is abnormal in the external device. Can be Further, when an abnormality of the aspect information occurs, it is possible to prevent continuous external output that enables the abnormality of the aspect information to be grasped in a short period of time.

Feature αi15. At least one of the predetermined information output means is that the number of occurrences of the predetermined event grasped based on the history information of the game stored in the history storage means is a predetermined reference number (initial reference number) or more. The gaming machine according to any one of features αi1 to αi14, wherein the aspect related information is output to the outside of the gaming machine as a condition.

According to the feature αi15, the mode-related information based on the unstable mode information derived when the number of occurrences of the predetermined event used for deriving the mode information does not reach the predetermined reference number is output to the outside of the gaming machine. It can be prevented. As a result, it is possible to prevent the manager of the gaming hall from taking an unnecessary action based on the fact that the external device such as the hall computer receives the mode-related information generated based on the unstable mode information. can do.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features αi1 to αi15. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, features S1-S8, features T1-T13, features U1-U8, features V1-V6, features W1-W11, features X1-X11, features Y1-Y11, features Z1-Z10, features a1-a3, features b1-. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, and features βA1 to βA. 4. Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αj group>
Feature αj1. When a predetermined event occurs due to the execution of a game, history storage execution means (normal entrance management processing in the main CPU 63) for storing history information of the game corresponding to it in the history storage means (normal counter area 231) Function to execute)
Information derivation means (function of executing the process of step S8601 in the main CPU 63) for deriving mode information (base value) corresponding to the result of the game using the history information stored in the history storage means,
Abnormality determining means for determining whether or not the aspect information is abnormal (in the 84th embodiment, a function of executing the processing of steps SJ605 and SJ606 in the main CPU 63, in the 85th and 87th embodiments, the main side). A function of executing the processes of steps SK102 and SK105 in the CPU 63, a function of executing the processes of steps SK402, SK405 and SK408 in the 86th embodiment).
Special processing executing means for executing special processing based on the abnormality determination means determining that the aspect information is abnormal (in the 84th embodiment, the main CPU 63 executes the processing of step SJ611, The function of executing the process of step SJ810 in the side CPU 63, the function of executing the processes of step SK202 and step SK205 in the main CPU 63 in the 85th embodiment, and the function of executing the process in steps SK502 and SK505 in the main CPU 63 in the 86th embodiment. A function of executing the process of step SK508, a function of executing the processes of steps SK602, SK604 and SK607 in the main CPU 63 in the 87th embodiment).
A gaming machine characterized by being equipped with.

According to the characteristic αj1, when the predetermined event occurs, the history information corresponding to the predetermined event is stored in the history storage means. By storing the history information in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, the mode information corresponding to the result of the game is derived using the history information stored in the history storage means, and the derived mode information is stored in the mode information storage means. As a result, it becomes possible to store and hold information for managing the number of occurrences or the frequency of occurrence of a predetermined event in the gaming machine, and it is preferable to manage the frequency of occurrence of the predetermined event by using this managed information. It becomes possible to do it. Further, when it is determined that the aspect information is abnormal, special processing is executed. Therefore, by confirming whether or not the special process has been executed, it is possible to recognize whether or not there is an abnormality in the aspect information.

Feature αj2. The special processing execution means performs the special processing as judgment result correspondence information (base value abnormal signal in the 84th embodiment, upper base value abnormal signal in the 85th embodiment) corresponding to the judgment result by the abnormality judging means. Lower base value abnormal signal, upper base value abnormal signal in the 86th embodiment, lower first base value abnormal signal and lower second base value abnormal signal, common base value abnormal signal in the 87th embodiment, upper side The gaming machine according to feature αj1, wherein processing for outputting a base value abnormality signal and a lower base value abnormality signal) to the outside of the gaming machine is executed.

According to the feature αj2, the determination result correspondence information corresponding to the determination result as to whether the aspect information is abnormal is externally output to an external device such as a hall computer. Therefore, it is possible to grasp the presence/absence of abnormality in the aspect information in the external device. This makes it possible to omit the work of the game hall manager who goes to the place where the gaming machine is installed and checks the mode information. Further, when a plurality of gaming machines are installed in the gaming hall, it is possible to collectively grasp the presence or absence of abnormality of the mode information in the plurality of gaming machines in the external device. As a result, it is possible to suitably manage the occurrence frequency of the predetermined event, while reducing the monitoring load on the manager of the game hall.

Feature αj3. Reference value information (a threshold value table 566 in the 84th to 85th and 87th embodiments, a threshold value table 573 in the 86th embodiment) that enables grasping a predetermined reference range (base normal range) of the aspect information is stored in advance. Provided predetermined information storage means (main side ROM 64),
The abnormality determining means determines whether the aspect information is within the predetermined reference range using the reference value information, and when the aspect information is not within the predetermined reference range, the aspect information is The gaming machine described in the feature αj1 or αj2, which is characterized by determining that it is abnormal.

According to the feature αj3, it is possible to determine whether or not there is an abnormality in the aspect information based on the reference value information stored in advance in the predetermined information storage means. Since the special process is performed when the aspect information is determined to be abnormal, it is possible to recognize the abnormality of the aspect information based on the execution of the special process. be able to.

Feature αj4. A predetermined threshold value (upper threshold value in the 84th to 87th embodiments) indicating an upper limit of the predetermined reference range is set in the reference value information,
The gaming machine according to feature αj3, wherein the abnormality determination means determines that the aspect information is abnormal when the aspect information exceeds the predetermined threshold value.

According to the feature αj4, it is possible to determine based on the reference value information stored in advance whether or not the aspect information is in an abnormal state in which it exceeds a predetermined threshold value. Since the special processing is executed when the aspect information is determined to be abnormal, the abnormal state in which the aspect information exceeds the predetermined threshold value based on the execution of the special processing. It is possible to understand that there is.

Feature αj5. A specific threshold value (a lower threshold value in the 84th to 85th and 87th embodiments, a lower first threshold value in the 86th embodiment) indicating the lower limit of the predetermined reference range is set in the reference value information. ,
The gaming machine according to feature αj3 or αj4, wherein the abnormality determination means determines that the aspect information is abnormal when the aspect information is below the specific threshold.

According to the feature αj5, it is possible to determine based on the reference value information stored in advance whether or not the aspect information is below the specific threshold and is in an abnormal state. In the abnormal state in which the aspect information is below the specific threshold value based on the execution of the special process, since the special process is performed when the aspect information is determined to be abnormal It is possible to understand that there is.

Feature αj6. The reference value information includes a predetermined threshold value indicating the upper limit of the predetermined reference range (upper threshold value in the 85th to 87th embodiments) and a specific threshold value indicating the lower limit of the predetermined reference range (85th and 87th implementations). Lower threshold in the embodiment, lower first threshold in the 86th embodiment),
The special processing execution means,
When the abnormality determining unit determines that the aspect information exceeds the predetermined threshold value, the first predetermined abnormality information (upper base value) indicating that the aspect information exceeds the predetermined threshold value as the special processing. First abnormality information output means for executing a process for outputting an abnormal signal) to the outside of the gaming machine (a function for executing the process of step SK202 in the main CPU 63 in the 85th embodiment, the main in the 86th embodiment) The function of executing the process of step S502 in the side CPU 63, and the function of executing the process of step SK604 in the main CPU 63 in the 87th embodiment),
When the abnormality determination unit determines that the aspect information is lower than the specific threshold value, the second predetermined abnormality information (85th, abnormal information indicating that the aspect information is lower than the specific threshold value as the special process). In order to output the lower base value abnormality signal in the 87th embodiment and the lower first base value abnormality signal in the 86th embodiment) to the outside of the gaming machine in a manner distinguishable from the first predetermined abnormality information. Second abnormality information output means for executing the process (the function of executing the process of step SK205 in the main CPU 63 in the 85th embodiment, the function of executing the process of step SK505 in the main CPU 63 in the 86th embodiment, In the 87th embodiment, the function of executing the process of step SK607 in the main CPU 63),
The gaming machine according to any one of the features αj3 to αj5.

According to the feature αj6, when the external device such as the hall computer receives the first predetermined abnormality information from the gaming machine, it is possible to understand that the aspect information is in an abnormal state in which the predetermined information exceeds the predetermined threshold. When the external device receives the second predetermined abnormality information from the gaming machine, it is possible to recognize that the aspect information is in an abnormal state that is below the specific threshold. Since the first predetermined abnormality information and the second predetermined abnormality information are externally output in a distinguishable manner, it is possible to prompt the manager of the game hall to take a response according to the state of the manner information with respect to the predetermined reference range in the external device.

Feature αj7. The reference value information includes a predetermined threshold value indicating the upper limit of the predetermined reference range (upper threshold value in the 86th embodiment) and a specific threshold value indicating the lower limit of the predetermined reference range (lower first value in the 86th embodiment). Threshold value) and a special threshold value (lower second threshold value in the 86th embodiment) smaller than the specific threshold value are set,
The special processing execution means, when the abnormality determination means determines that the aspect information is below the special threshold, indicates that the aspect information is below the special threshold as the special processing. Third abnormality information output means for executing a process for outputting predetermined abnormality information (lower second base value abnormality signal in the 86th embodiment) to the outside of the gaming machine (of the main CPU 63 in the 86th embodiment) The game machine according to any one of the features αj3 to αj6, which is provided with a function of executing the process of step SK508).

According to the characteristic αj7, when the external device such as the hall computer receives the third predetermined abnormality information from the gaming machine, it is possible to grasp that the mode information is in a state of being significantly lower than the lower limit of the predetermined reference range, and thus the game hall. The administrator of can be urged to take prompt action.

Feature αj8. The reference value information includes a predetermined threshold value indicating the upper limit of the predetermined reference range (upper threshold value in the 87th embodiment) and a specific threshold value indicating the lower limit of the predetermined reference range (lower threshold value in the 87th embodiment). And are set,
The special processing execution means,
When the abnormality determining unit determines that the aspect information exceeds the predetermined threshold value, the first predetermined abnormality information (upper base value) indicating that the aspect information exceeds the predetermined threshold value as the special processing. First abnormality information output means (a function of executing the processing of step SK604 of the main CPU 63 in the 87th embodiment) for performing processing for outputting an (abnormal signal) to the outside of the gaming machine,
When the abnormality determination unit determines that the aspect information is below the specific threshold, the second predetermined abnormality information (the 87th of the 87th) indicating that the aspect information is below the specific threshold as the special processing. The second abnormality information output means (in the 87th embodiment) for executing the processing for outputting the lower side base value abnormality signal in the embodiment) to the outside of the gaming machine in a manner distinguishable from the first predetermined abnormality information. A function of executing the process of step SK607 of the main CPU 63),
Common in both cases where the abnormality determination means determines that the aspect information is above the predetermined threshold value, and when the abnormality determination means determines that the aspect information is below the specific threshold value. Then, as the special processing, common abnormality information for executing processing for outputting common predetermined abnormality information (common base value abnormality signal) indicating that the aspect information is not within the predetermined reference range to the outside of the gaming machine. Output means (function of executing the process of step SK602 of the main CPU 63 in the 87th embodiment);
The gaming machine according to any one of the features αj3 to αj7.

According to the characteristic αj8, as the connection mode between the gaming machine and the external device such as the hall computer, the external mode receives only the common predetermined abnormal information, and the first predetermined abnormal information and the second predetermined abnormal information are received. The connection mode to be performed can be selected. When the connection mode in which the external device receives only the common predetermined abnormality information is selected, it can be grasped that the mode information is not within the predetermined reference range. In addition, when the connection mode that causes the external device to receive the first predetermined abnormality information and the second predetermined abnormality information is selected, the state information is above the predetermined threshold and the state information is below the specific threshold. And can be grasped in an identifiable manner.

Feature αj9. A latest storage area (current area 311) for storing the latest aspect information derived by the information deriving means;
A past storage area (first to third history areas 312 to 314) that stores the aspect information derived by the information deriving unit before the aspect information stored in the latest storage area,
Equipped with
The abnormality determination means determines whether or not the aspect information stored in the past storage area is abnormal based on the occurrence of a predetermined determination trigger (mainly in the 84th embodiment. The side CPU 63 has a function of executing the processing of steps SJ801 to SJ809, and in the 85th to 87th embodiments, the main CPU 63 has a function of executing the processing of steps SK301 to SK307).
The special processing executing means performs information (corresponding to the judgment result by the past abnormality judging means as the special processing) (base value abnormal signal in the 84th embodiment, upper base value abnormal signal and lower base value in the 85th embodiment). Value abnormality signal, upper base value abnormality signal in the 86th embodiment, lower first base value abnormality signal and lower second base value abnormality signal, common base value abnormality signal, upper base value abnormality in the 87th embodiment Signal and lower side base value abnormal signal) past abnormality information output means for executing processing for outputting to the outside of the gaming machine (in the 84th embodiment, a function for executing the processing of step SJ810 in the main CPU 63, 85th embodiment) The gaming machine according to any one of the features αj1 to αj8, which is characterized by having a function of executing the process of step SK308 in the main CPU 63 in the 87th embodiment.

According to the feature αj9, since the latest aspect information and the past aspect information derived before that are stored, the occurrence frequency of the predetermined event is grasped not only in the latest but also in the past. It becomes possible. Further, since the information corresponding to the determination result as to whether the aspect information stored in the past storage area is abnormal is externally output to the external device such as the hall computer, the abnormality of the aspect information has occurred in the past. It is possible to grasp that. As a result, it is possible to reduce the possibility that an abnormality in the aspect information will be overlooked.

Feature αj10. The gaming machine according to feature αj9, wherein the predetermined determination trigger is that supply of operating power is started.

According to the characteristic αj10, by confirming whether or not the predetermined abnormality information is output to the outside of the gaming machine at the time of starting the supply of the operating power, it is possible to grasp whether or not the abnormality of the mode information has occurred in the past. You can As a result, it is possible to reduce the possibility that an abnormality in the aspect information will be overlooked.

Feature αj11. The special processing execution means executes the special processing based on the occurrence of a periodically generated output trigger (the value of the timer counter for the base value in the work area 221 for specific control becomes "0"). The gaming machine according to any one of the features αj1 to αj10.

According to the feature αj11, the special processing can be periodically executed when the abnormality determination unit determines that the aspect information is abnormal while suppressing the frequency of performing the special processing. Therefore, by confirming that the special process has been executed, it is possible to periodically grasp that the abnormality determination unit determines that the aspect information is abnormal. Further, when the abnormality determining unit determines that the aspect information is abnormal, it is possible to prevent the special processing from being continuously performed in a short period of time.

Feature αj12. At least one of the special processing execution means is that the number of occurrences of the predetermined event grasped based on the history information of the game stored in the history storage means is a predetermined reference number (initial reference number) or more. The gaming machine according to any one of the features αj1 to αj11, characterized in that the special processing is executed as a condition.

According to the feature αj12, the abnormality determination unit makes a determination based on the unstable aspect information derived when the number of occurrences of the predetermined event used for deriving the aspect information does not reach the predetermined reference number, and the determination is made. It is possible to prevent the special processing from being executed when it is determined that the mode information is abnormal. As a result, it is possible to prevent the game hall manager from taking an unnecessary action by performing special processing based on the unstable mode information.

For the configurations of the features αj1 to αj12, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, and features βA1 to βA. 4. Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αk group>
Features αk1. When a predetermined event occurs due to the execution of a game, history storage execution means (normal entrance management processing in the main CPU 63) for storing history information of the game corresponding to it in the history storage means (normal counter area 231) Function to execute)
Information derivation means (function of executing the process of step S8601 in the main CPU 63) for deriving mode information (base value) corresponding to the result of the game using the history information stored in the history storage means,
Reference value information (a threshold value table 566 in the 84th to 85th and 87th embodiments, a threshold value table 573 in the 86th embodiment) that enables grasping of a predetermined reference range (base normal range) of the aspect information is stored in advance. Specified information storage means (main side ROM 64),
It is determined whether the aspect information is within the predetermined reference range by using the reference value information, and the aspect information is determined to be abnormal when the aspect information is not within the predetermined reference range. Abnormality determination means (a function of executing the processing of steps SJ605 and SJ606 in the main CPU 63 in the 84th embodiment, a function of executing the processing of steps SK102 and SK105 in the main CPU 63 in the 85th and 87th embodiments. , A function of executing the processing of step SK402, step SK405 and step SK408 in the 86th embodiment),
A gaming machine characterized by being equipped with.

According to the characteristic αk1, when the predetermined event occurs, the history information corresponding to the predetermined event is stored in the history storage means. By storing the history information in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, the mode information corresponding to the result of the game is derived using the history information stored in the history storage means, and the derived mode information is stored in the mode information storage means. As a result, it becomes possible to store and hold information for managing the number of occurrences or the frequency of occurrence of a predetermined event in the gaming machine, and it is preferable to manage the frequency of occurrence of the predetermined event by using this managed information. It becomes possible to do it. Further, the reference value information is stored in advance in the predetermined information storage means. Therefore, in the gaming machine, it is possible to determine whether there is an abnormality in the aspect information based on the reference value information.

Features αk2. A predetermined threshold value (upper threshold value in the 84th to 87th embodiments) indicating an upper limit of the predetermined reference range is set in the reference value information,
The gaming machine according to feature αk1, wherein the abnormality determination means determines that the aspect information is abnormal when the aspect information exceeds the predetermined threshold value.

According to the feature αk2, it is possible to determine based on the reference value information stored in advance whether or not the aspect information is in an abnormal state in which it exceeds the predetermined threshold value.

Features αk3. A specific threshold value (a lower threshold value in the 84th to 85th and 87th embodiments, a lower first threshold value in the 86th embodiment) indicating the lower limit of the predetermined reference range is set in the reference value information. ,
The gaming machine according to feature αk1 or αk2, wherein the abnormality determination means determines that the aspect information is abnormal when the aspect information is below the specific threshold.

According to the feature αk3, it is possible to determine based on the reference value information stored in advance whether or not the aspect information is below the specific threshold and is in an abnormal state.

Features αk4. Judgment result correspondence information corresponding to the judgment result by the abnormality judging means (base value abnormal signal in the 84th embodiment, upper base value abnormal signal and lower base value abnormal signal in the 85th embodiment, 86th embodiment) The upper base value abnormality signal, the lower first base value abnormality signal and the lower second base value abnormality signal in the embodiment, the common base value abnormality signal, the upper base value abnormality signal and the lower base value abnormality signal in the 87th embodiment. ) Is output to the outside of the gaming machine (in the 84th embodiment, the main CPU 63 executes the process of step SJ611, the main CPU 63 executes the process of step SJ810, and the 85th embodiment). In the embodiment, the function of executing the processing of steps SK202 and SK205 in the main CPU 63, in the 86th embodiment, the function of executing the processing of steps SK502, SK505 and SK508 in the main CPU 63, The game machine according to any one of features αk1 to αk3, which is provided with a function of executing the processing of steps SK602, SK604, and SK607 in the side CPU 63.

According to the feature αk4, the determination result correspondence information corresponding to the determination result as to whether the aspect information is abnormal is externally output to the external device such as the hall computer. Therefore, it is possible to grasp the presence/absence of abnormality in the aspect information in the external device. This makes it possible to omit the work of the game hall manager who goes to the place where the gaming machine is installed and checks the mode information. It is determined whether or not there is an abnormality in the mode information in the gaming machine based on the reference value information stored in advance in the predetermined information storage means, which has the configuration of the above characteristic αk1. Accordingly, it is possible to grasp the presence/absence of abnormality of the aspect information in the external device, without the need to set the predetermined reference information of the aspect information in the external device. Further, when a plurality of gaming machines are installed in the gaming hall, it is possible to collectively grasp the presence or absence of abnormality of the mode information in the plurality of gaming machines in the external device. As a result, it is possible to suitably manage the occurrence frequency of the predetermined event, while reducing the monitoring load on the manager of the game hall. Further, the amount of data of the information to be externally output can be reduced in order to make it possible to recognize whether or not there is an abnormality in the aspect information, as compared with a configuration in which the aspect information itself is externally output.

Features αk5. The reference value information includes a predetermined threshold value indicating the upper limit of the predetermined reference range (upper threshold value in the 85th to 87th embodiments) and a specific threshold value indicating the lower limit of the predetermined reference range (85th and 87th implementations). Lower threshold in the embodiment, lower first threshold in the 86th embodiment),
The predetermined information output means,
When the abnormality determining unit determines that the aspect information exceeds the predetermined threshold value, the first predetermined abnormality information (upper side) indicating that the aspect information exceeds the predetermined threshold value as the determination result correspondence information. First abnormality information output means for outputting a base value abnormality signal) to the outside of the gaming machine (a function of executing the process of step SK202 in the main CPU 63 in the 85th embodiment, a step in the main CPU 63 in the 86th embodiment) A function of executing the process of S502, a function of executing the process of step SK604 in the main CPU 63 in the 87th embodiment),
When the abnormality determination unit determines that the aspect information is below the specific threshold value, the second predetermined abnormality information indicating that the aspect information is below the specific threshold value as the determination result correspondence information (second 85, the lower base value abnormal signal in the 87th embodiment, the lower first base value abnormal signal in the 86th embodiment) is output to the outside of the gaming machine in a manner distinguishable from the first predetermined abnormal information. Second abnormality information output means (function to execute the process of step SK205 in the main CPU 63 in the 85th embodiment, function to execute the process of step SK505 in the main CPU 63 in the 86th embodiment, 87th embodiment In the embodiment, the function of executing the process of step SK607 in the main CPU 63),
The gaming machine described in the feature αk4.

According to the feature αk5, when the external device such as the hall computer receives the first predetermined abnormality information from the gaming machine, it is possible to grasp that the mode information is in an abnormal state in which the predetermined information exceeds the predetermined threshold. When the external device receives the second predetermined abnormality information from the gaming machine, it is possible to recognize that the aspect information is in an abnormal state that is below the specific threshold. Since the first predetermined abnormality information and the second predetermined abnormality information are externally output in a distinguishable manner, it is possible to prompt the manager of the game hall to take a response according to the state of the manner information with respect to the predetermined reference range in the external device.

Features αk6. The reference value information includes a predetermined threshold value indicating the upper limit of the predetermined reference range (upper threshold value in the 86th embodiment) and a specific threshold value indicating the lower limit of the predetermined reference range (lower first value in the 86th embodiment). Threshold value) and a special threshold value (lower second threshold value in the 86th embodiment) smaller than the specific threshold value are set,
When the abnormality determination unit determines that the aspect information is below the special threshold value, the predetermined information output unit indicates that the aspect information is below the special threshold value as the determination result correspondence information. Third abnormality information output means for outputting the third predetermined abnormality information (lower second base value abnormality signal in the 86th embodiment) to the outside of the gaming machine (processing of step SK508 of the main CPU 63 in the 86th embodiment) The game machine according to the feature αk4 or αk5.

According to the feature αk6, when the external device such as the hall computer receives the third predetermined abnormality information from the gaming machine, it is possible to grasp that the mode information is in a state of being significantly lower than the lower limit of the predetermined reference range, and thus the game hall. The administrator of can be urged to take prompt action.

Features αk7. The reference value information includes a predetermined threshold value indicating the upper limit of the predetermined reference range (upper threshold value in the 87th embodiment) and a specific threshold value indicating the lower limit of the predetermined reference range (lower threshold value in the 87th embodiment). And are set,
The predetermined information output means,
When the abnormality determining unit determines that the aspect information exceeds the predetermined threshold value, the first predetermined abnormality information (upper side) indicating that the aspect information exceeds the predetermined threshold value as the determination result correspondence information. A first abnormality information output unit (a function for executing the process of step SK604 of the main CPU 63 in the 87th embodiment) that outputs a base value abnormality signal) to the outside of the gaming machine;
When the abnormality determination unit determines that the aspect information is below the specific threshold value, the second predetermined abnormality information indicating that the aspect information is below the specific threshold value as the determination result correspondence information (second 87. The second abnormality information output means (the main CPU 63 in the 87th embodiment) which outputs the lower base value abnormality signal in the 87th embodiment) to the outside of the gaming machine in a manner distinguishable from the first predetermined abnormality information. A function for executing the processing of step SK607),
Common in both cases where the abnormality determination unit determines that the aspect information is above the predetermined threshold value, and when the abnormality determination unit determines that the aspect information is below the specific threshold value. Then, as the determination result correspondence information, a common abnormality information output unit (common abnormality information output unit) that outputs common predetermined abnormality information (common base value abnormality signal) indicating that the aspect information is not within the predetermined reference range (the first abnormality information) to the outside of the gaming machine. 87, the function of executing the process of step SK602 of the main CPU 63 in the embodiment of FIG.
The gaming machine according to any one of the features αk4 to αk6.

According to the feature αk7, as the connection mode between the gaming machine and the external device such as the hall computer, the external mode receives only the common predetermined abnormal information, and the first predetermined abnormal information and the second predetermined abnormal information are received. The connection mode to be performed can be selected. When the connection mode in which the external device receives only the common predetermined abnormality information is selected, it can be grasped that the mode information is not within the predetermined reference range. In addition, when the connection mode that causes the external device to receive the first predetermined abnormality information and the second predetermined abnormality information is selected, the state information is above the predetermined threshold and the state information is below the specific threshold. And can be grasped in an identifiable manner.

Features αk8. A latest storage area (current area 311) for storing the latest aspect information derived by the information deriving means;
A past storage area (first to third history areas 312 to 314) that stores the aspect information derived by the information deriving unit before the aspect information stored in the latest storage area,
Equipped with
The abnormality determination means determines whether or not the aspect information stored in the past storage area is abnormal based on the occurrence of a predetermined determination trigger (mainly in the 84th embodiment. The side CPU 63 has a function of executing the processing of steps SJ801 to SJ809, and in the 85th to 87th embodiments, the main CPU 63 has a function of executing the processing of steps SK301 to SK307).
The predetermined information output means, as the determination result correspondence information, information corresponding to the determination result by the past abnormality determination means (a base value abnormality signal in the 84th embodiment, an upper base value abnormality signal and a lower value in the 85th embodiment). Side base value abnormality signal, an upper base value abnormality signal in the 86th embodiment, a lower first base value abnormality signal and a lower second base value abnormality signal, a common base value abnormality signal, an upper base in the 87th embodiment Past abnormality information output means for outputting a value abnormality signal and a lower base value abnormality signal) to the outside of the gaming machine (in the 84th embodiment, a function of executing the processing of step SJ810 in the main CPU 63, the 85th to 87th) In the embodiment, the gaming machine according to any one of the features αk4 to αk7, which is provided with a function of executing the process of step SK308 in the main CPU 63).

According to the feature αk8, since the latest mode information and the past mode information derived before that are stored, the frequency of occurrence of the predetermined event is grasped not only in the latest but also in the past. It becomes possible. Further, since the information corresponding to the determination result as to whether the aspect information stored in the past storage area is abnormal is externally output to the external device such as the hall computer, the abnormality of the aspect information has occurred in the past. It is possible to grasp that. As a result, it is possible to reduce the possibility that an abnormality in the aspect information will be overlooked.

Features αk9. The gaming machine according to feature αk8, wherein the predetermined determination trigger is that supply of operating power is started.

According to the characteristic αk9, by confirming whether or not the predetermined abnormality information is output to the outside of the gaming machine at the time of starting the supply of the operating power, it is possible to grasp whether or not the abnormality of the mode information has occurred in the past. You can As a result, it is possible to reduce the possibility that an abnormality in the aspect information will be overlooked.

Features αk10. The predetermined information output means is based on the occurrence of a periodically generated output trigger (the value of the base value timer counter in the specific control work area 221 becomes “0”), and the determination result correspondence information. The gaming machine according to any one of the features αk4 to αk9, wherein the gaming machine is output to the outside of the gaming machine.

According to the feature αk10, while suppressing the frequency of outputting the determination result correspondence information to the outside of the gaming machine, when the abnormality determination means determines that the mode information is abnormal, the determination result correspondence information is periodically provided. Can be output to the outside. Therefore, an external device such as a hall computer that receives the determination result correspondence information from the gaming machine can periodically recognize whether or not the mode information is abnormal. Further, it is possible to prevent the determination result correspondence information from being continuously output to the outside in a short period of time.

Features αk11. At least one of the predetermined information output means is that the number of occurrences of the predetermined event grasped based on the history information of the game stored in the history storage means is a predetermined reference number (initial reference number) or more. The gaming machine according to any one of the features αk4 to αk10, characterized in that the determination result correspondence information is output to the outside of the gaming machine as a condition.

According to the feature αk11, the determination result correspondence information based on the unstable aspect information derived when the number of occurrences of the predetermined event used for deriving the aspect information does not reach the predetermined reference number is output to the outside of the gaming machine. It is possible to prevent that. As a result, based on the fact that the external device such as the hall computer receives the determination result correspondence information generated based on the unstable aspect information, the manager of the gaming hall may take unnecessary correspondence. Can be prevented.

For the configurations of the features αk1 to αk11, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, and features βA1 to βA. 4. Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the inventions related to the characteristic αi group, the characteristic αj group, and the characteristic αk group, it is possible to solve the following problems.

Pachinko machines and slot machines are known as game machines. For example, in a pachinko machine, the game machine front face section is provided with a dish storage section for storing the game balls given to the player, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, it is necessary to manage the gaming machine appropriately, and there is still room for improvement in this respect.

<Characteristic αl group>
Features α11. In a gaming machine where a game is played using a game medium (game ball),
Profit is granted based on the occurrence of a profit-giving event (the entry of the game ball into the general winning opening 31, the special electric winning device 32, the first working opening 33, and the second working opening 34) as the game is played. A profit giving means (a function of the main CPU 63 for executing the processing of steps S316 and S317);
The total amount of the profits given in the predetermined period to the total number of the game media used in the predetermined period (the total number of the game balls discharged from the game area PA of the pachinko machine 10) (the total payout number of the game balls) ) A predetermined calculation means for calculating predetermined ratio information (ball output rate) corresponding to the ratio (in the 89th and 92nd embodiments, the function of executing the process of step SL103 in the main CPU 63, the step SL208 in the main CPU 63, and A function of executing the processing of step SL220, a function of executing the processing of steps SL510 and SL518 in the main CPU 63 in the 90th embodiment, and a processing of steps SL708 and SL716 of the main CPU 63 in the 91th embodiment. Function),
A gaming machine characterized by being equipped with.

According to the characteristic α11, based on the predetermined ratio information, it is possible to grasp the ratio of the total amount of profits given in the predetermined period to the total number of game media used in the predetermined period. By making it possible to grasp the predetermined ratio information, the total amount of profits given in the predetermined period with respect to the total number of game media used in the predetermined period becomes abnormally high, and it is used in the predetermined period. It is possible to grasp an anomaly in which the total amount of profits given in the predetermined period with respect to the total number of game media is unnaturally low.

The predetermined period may be a period until a predetermined time elapses or a period until a predetermined reference trigger is generated. When the predetermined period is a period until the predetermined reference opportunity occurs, the predetermined reference opportunity may be that the total number of used game media reaches the reference number.

Features α12. Utilization measuring means for measuring the total number of the used game media (function of executing the processes of steps SL102 and SL103 in the main CPU 63),
An award measurement means (a function of executing the process of step SL103 in the main CPU 63) for measuring the total amount of the award given.
Equipped with
The predetermined calculation means calculates the predetermined ratio information by using information (total payout number of game balls) corresponding to the total amount of the profit measured by the addition measurement means,
As a game state, a first game state (a game state that is neither the open/close execution mode nor the high frequency support mode) and a second game state (a game that is the open/close execution mode) in which the expected value of the profit to be given is different State, game state that is a high frequency support mode) exists,
The usage measuring means measures the total number of the game media used without distinguishing the first gaming state and the second gaming state,
The gaming machine according to feature α11, wherein the grant measuring means measures the total amount of the profits granted without distinguishing between the first gaming state and the second gaming state.

According to the characteristic α12, the predetermined ratio information is calculated by using the information corresponding to the total amount of the added profit measured without distinguishing the first gaming state and the second gaming state. Therefore, based on the predetermined ratio information, an abnormality in the ratio of the total amount of profits given to the total number of game media used in the first game state, and the total number of game media used in the second game state It is possible to grasp the anomaly in the ratio of the total amount of profit given to the. A structure for measuring the total number of game media used in the first game state and a structure for separately measuring the total number of game media used in the second game state are provided separately. By comparison, the configuration for measuring the total number of used game media can be simplified. Further, in comparison with a configuration in which a configuration for measuring the total amount of profit in the first gaming state and a configuration for measuring the total amount of profit in the second gaming state are separately provided, The configuration for measuring the total amount can be simplified.

Features α13. A game area (game area PA) in which game balls flow down as the game medium,
Predetermined ball entering means (general winning opening 31, special electric winning device 32, first operating port 33, second operating port 34) into which a game ball flowing down in the game area can enter.
Predetermined detection means (first winning opening detection sensor 42a, second winning opening detection sensor 43a, third winning opening detection sensor 44a, special electricity detection sensor 45a, first operation) for detecting a game ball that has entered the predetermined entering means. A mouth detecting sensor 46a, a second working mouth detecting sensor 47a),
Based on the fact that the game ball has been detected by the predetermined detection means, specific storage execution means (step SL102 in the main CPU 63 in which the corresponding information is stored in the specific storage means (entered ball number counter area 596)) Function that executes the process of
Equipped with
The profit granting means stores a predetermined number of game balls as a grant of the profit based on the fact that the information corresponding to the detection of the game ball being detected by the predetermined detecting means is stored in the specific storage means. Processing for allowing the person to be given (the processing of steps S316 and S317 in the main CPU 63),
The gaming machine is provided with a plurality of ball-entering means including the predetermined ball-injecting means as ball-injecting means capable of entering a game ball flowing down through the game area and ejecting the entered game ball from the game area. (Outward opening 24a, general winning opening 31, special electric winning device 32, first working opening 33, second working opening 34,),
A game ball flowing down the game area is discharged from the game area by entering any of the plurality of ball entering means.
As a detecting means for detecting a game ball entering any of the plurality of ball entering means, a plurality of detecting means including the predetermined detecting means (first winning opening detecting sensor 42a, second winning opening detecting sensor 43a, The third winning opening detection sensor 44a, the special electricity detection sensor 45a, the first working opening detection sensor 46a, the second working opening detection sensor 47a, the out opening detection sensor 48a),
The game ball entered in any one of the plurality of ball entering means is configured to be detected by any of the plurality of detecting means,
The predetermined calculation means is information corresponding to the ratio of the total number of provided game balls to the total number of discharged game balls discharged from the game area in the predetermined period (ball-out rate of the entire last four unit calculation periods, The payout rate in the first calculation period, the payout rate of the entire last 10 unit calculation periods, and the payout rate in the second calculation period) are calculated as the predetermined ratio information. Game machine.

According to the characteristic α13, the game ball flowing down through the game area is discharged from the game area by entering one of the plurality of ball entering means, and also enters one of the plurality of ball entering means. The game sphere played is configured to be detected by any of a plurality of detecting means. Therefore, it is possible to measure all the game balls discharged from the game area. Further, the predetermined ratio information is information corresponding to the ratio of the total number of game balls provided to the total number of discharged game balls in the predetermined period. Therefore, by making it possible to grasp the predetermined ratio information, the ratio of the total granted number of game balls to the total discharged number of game balls discharged from the game area during the predetermined period is abnormally high, and the game during the predetermined period It is possible to grasp an abnormality in which the ratio of the total number of game balls given to the total number of game balls discharged from the area is unnaturally low.

Features α14. Predetermined ratio storage means for sequentially storing the predetermined ratio information (the most recent area 606b of the first calculation period, the first history area 606c of the first calculation period, the second history area 606d of the first calculation period, and the most recent second calculation period). The area 607b, the first history area 607c of the second calculation period, the second history area 607d of the second calculation period) are provided, the gaming machine according to any one of the features αl1 to αl3.

According to the feature α14, it is possible to individually grasp a plurality of predetermined ratio information.

Features α15. The predetermined period corresponds to a predetermined number of unit periods (unit calculation period) (4 times or 10 times in the 89th to 92nd embodiments),
The gaming machine according to any one of features αl1 to αl4, wherein the predetermined calculation means calculates the predetermined ratio information every time the unit period is completed.

According to the characteristic α15, the predetermined ratio information can be updated at intervals shorter than the predetermined period. If the configuration is such that the predetermined ratio information is updated each time the predetermined period ends, it is used in the period from the latter half of the front (first) predetermined period to the rear half of the rear (second) predetermined period. Even if an abnormality in which the ratio of the total amount of profits given to the total number of game media in the period concerned becomes unnaturally high or abnormally decreases, the predetermined ratio information in the front side predetermined period and the rear side It is possible that the abnormality cannot be found based on the predetermined ratio information in the predetermined period. On the other hand, since the predetermined ratio information is updated at intervals shorter than the predetermined period, the ratio of the total amount of profits given in the predetermined period to the total number of game media used in the predetermined period is incorrect. It is possible to reduce the possibility that the occurrence of an abnormality that naturally increases or an abnormality that naturally decreases becomes overlooked.

Features α16. A first predetermined ratio storage unit (first unit update area 606a, second unit update area 607a) that stores the predetermined ratio information calculated by the predetermined calculation unit when the unit period is completed;
Second predetermined ratio storage means (the first calculation period nearest area 606b, the second calculation period nearest area 607b) for storing the predetermined ratio information calculated by the predetermined calculation means when the predetermined time period is completed,
Means for executing notification for enabling recognition of each of the predetermined ratio information stored in the first predetermined ratio storage means and the predetermined ratio information stored in the second predetermined ratio storage means (main side) A function of executing the processing of step SL312 in the CPU 63),
The gaming machine according to the feature α15, which is characterized in that

According to the characteristic α16, the predetermined ratio information can be grasped by storing the predetermined ratio information calculated by the predetermined calculation means when the unit period is completed. By making it possible to grasp the predetermined ratio information calculated by the predetermined calculating means when the unit period is completed, it is possible to grasp the abnormality at an early stage when an abnormality occurs in the predetermined ratio information. As a result, the manager of the game hall can take prompt action against the abnormality. Further, by storing the predetermined ratio information calculated by the predetermined calculation means when the predetermined period is completed, the ratio information can be grasped. By making it possible to grasp the predetermined ratio information calculated by the predetermined calculation means when the predetermined period is completed, it is possible to monitor the predetermined ratio information for each predetermined period.

Features α17. Means for storing the predetermined ratio information in the predetermined period calculated by the predetermined calculating means at a predetermined timing (first history area 606c in the first calculation period, second history area 606d in the first calculation period, second calculation A first history area 607c of a period, a second history area 607d of a second calculation period),
Means for storing the predetermined ratio information in the predetermined period started by the completion of the predetermined period to be calculated at the predetermined timing (the area closest to the first calculation period 606b, the first calculation period of the first area). A history area 606c, a latest area 607b of the second calculation period, a first history area 607c of the second calculation period),
The gaming machine according to the feature α15 or α16, which is characterized by comprising:

According to the characteristic α17, the history of the predetermined ratio information can be stored and grasped at predetermined time intervals. By making it possible to grasp the past predetermined ratio information, it is possible to reduce the frequency with which the manager of the game hall confirms the predetermined ratio information, and reduce the monitoring load on the predetermined ratio information by the game hall manager. Further, when an abnormality in the predetermined ratio information is detected, it is possible to trace back from a time when the abnormality has occurred, in a past manner.

In the configuration including the characteristic α15, wherein the predetermined ratio information is calculated every time the unit period ends, the predetermined ratio information is stored because the interval for storing the history of the predetermined ratio information is the predetermined period interval longer than the unit period. It is possible to grasp the predetermined ratio information in a wide range while suppressing an increase in the number of ratio information.

Features α18. Specific ratio information corresponding to the ratio of the total amount of the profits given in the specific period to the total number of the game media used in the specific period (the entire unit calculation period for 10 times) (the unit for the last 10 times) Specific calculation means for calculating the payout rate in the calculation period and the payout rate in the second calculation period (in the 89th and 92nd embodiments, the function of executing the process of step SL220 in the main CPU 63, the 90th embodiment). Any one of the features αl1 to αl7 characterized in that the main CPU 63 has a function of executing the process of step SL518, and the ninety-first embodiment has a function of executing the process of step SL716 of the main CPU 63). Gaming machine described in.

According to the characteristic α18, since the specific ratio information is calculated in addition to the predetermined ratio information, detailed information about the ratio of the total amount of profits to the total number of used game media is grasped. It can be possible. As a result, it is possible to prevent the abnormality of the ratio of the total amount of the profits given to the total number of the used game media from being overlooked.

Features α19. The gaming machine according to feature α18, wherein a part of the specific period overlaps at least a part of the predetermined period.

According to the characteristic α19, details about the period in which the predetermined period overlaps with the specific period, and the ratio of the total amount of profits given in the period to the total number of game media used in the period before and after the period. It is possible to grasp various information. As a result, it is possible to prevent the abnormality of the ratio of the total amount of the profits given to the total number of the used game media from being overlooked.

Feature αl10. The predetermined period corresponds to a predetermined number of unit periods (unit calculation period) (four times in the 89th to 92nd embodiments),
The specific period corresponds to a specific number of the unit period (10 times in the 89th to 92nd embodiments),
The predetermined calculation means calculates the predetermined ratio information each time the unit period is completed,
10. The gaming machine described in the characteristic α18 or α19, wherein the specific calculating means calculates the specific ratio information every time the unit period is completed.

According to the feature α10, each time the unit period is completed, the predetermined ratio information in the predetermined period that is the predetermined number of unit periods and the specific ratio information in the specific period that is the specific number of unit periods are calculated. Accordingly, it is possible to reduce the possibility that the abnormality of the predetermined ratio information in the predetermined period is overlooked, and reduce the possibility that the abnormality of the specific ratio information in the specific period is overlooked. Further, since the timing for calculating the predetermined ratio information and the timing for calculating the specific ratio information are common, the configuration for grasping the timing for calculating the predetermined ratio information and the specific ratio information can be simplified. ..

Features α11. The predetermined period corresponds to a predetermined number of unit periods (unit calculation period) (four times in the 89th to 92nd embodiments),
The gaming machine, unit ratio information (ball-out rate in the unit calculation period) corresponding to the ratio of the total amount of the profit given in the unit period to the total number of the game media used in the unit period, and A unit storage area (each storage of the first management buffer 601) for storing unit target information, which is any one of the information (total payout number of game balls in the unit calculation period) necessary when calculating the unit ratio information. Areas 601a to 601d, respective storage areas 602a to 602j of the second management buffer 602, respective storage areas 616a to 616j of the common management buffer 616, and respective payout rate counters 621a to 621j of the common management counter area 621, the predetermined number The above-described unit period correspondence storage means (first management buffer 601, second management buffer 602, common management buffer 616, common management counter area 621) is provided,
The gaming machine according to any one of features αl1 to αl10, wherein the predetermined calculation means calculates the predetermined ratio information using information stored in a plurality of the unit storage areas.

According to the characteristic α11, a predetermined number or more of unit target information is stored, and the predetermined ratio information is calculated using the plurality of stored unit target information. Compared to the configuration in which one piece of information is used to calculate the predetermined ratio information, the information used for calculating the predetermined ratio information can be updated in detail. Further, it is possible to reduce the data amount of each piece of information stored for calculating the predetermined ratio information.

Features α12. The gaming machine according to feature α111, wherein the unit target information is the unit ratio information.

According to the characteristic α12, a predetermined number or more of unit ratio information is stored, and the predetermined ratio information is calculated using the plurality of stored unit ratio information. Therefore, a plurality of pieces of information required for calculating the unit ratio information are stored, and the predetermined ratio information is stored in comparison with the configuration in which the predetermined ratio information is calculated using the plurality of pieces of information. The data amount of information can be reduced.

Feature αl13. The predetermined calculation means uses the information stored in the plurality of unit storage areas based on that the unit target information is newly stored in the unit period correspondence storage means, and calculates the predetermined ratio information. The gaming machine according to the characteristic α11 or α12, which is characterized by being calculated.

According to the characteristic α13, each time the unit target information is newly stored in the unit period correspondence storage unit and the information stored in the unit calculation period correspondence storage unit is updated, the unit target information is stored in the unit calculation period correspondence storage unit. By calculating the predetermined ratio information based on the existing information, the predetermined ratio information can be updated with high frequency.

Feature αl14. The predetermined number is less than the number of unit storage areas,
The predetermined calculation means includes the unit storage area in which the latest unit target information is stored, including the unit storage area, and the predetermined number of the unit storage areas that are consecutive based on the unit period corresponding to the latest unit target information. The gaming machine according to any one of features α11 to α13, wherein the predetermined ratio information is calculated using the unit target information stored in.

According to the characteristic α14, the unit objects stored in the predetermined number of unit storage areas consecutively including the unit storage area storing the latest unit object information based on the unit period corresponding to the latest unit object information. By calculating the predetermined ratio information using the information, it is possible to calculate the predetermined ratio information in the entire unit period of the latest predetermined number.

Features α115. The unit storage areas in which the unit target information is stored in the plurality of unit storage areas are configured to be sequentially changed in a predetermined order,
The gaming machine is a storage target storage unit (first write pointer 603) that stores information that enables specification of the type of the unit storage area that is a target for storing the next unit target information among the plurality of unit storage areas. , A second write pointer 604, a common write pointer 617),
The gaming machine according to feature α114, wherein the predetermined calculation unit specifies the unit storage area in which the most recent unit target information is stored, based on information stored in the storage target storage unit.

According to the characteristic α115, the nearest unit target is stored by using the storage target storage unit provided to specify the type of the unit storage area that is the target of storing the next unit target information among the plurality of unit storage areas. A unit storage area in which information is stored is specified. Therefore, it is possible to specify the unit storage area in which the latest unit target information is stored, without the need for a dedicated configuration for specifying the unit storage area in which the latest unit target information is stored.

Features α116. Specific ratio information corresponding to the ratio of the total amount of the profits given in the specific period to the total number of the game media used in the specific period (the last 10 unit calculation periods, the second calculation period) (latest A specific calculation means (in the 89th and 92nd embodiments, a function of executing the process of step SL220 in the main CPU 63 in the 89th and 92nd embodiments) for calculating the payout rate in the entire unit calculation period for 10 times, and the payout rate in the second calculation period. A function of executing the process of step SL518 in the main CPU 63 in the 90th embodiment, and a function of executing the process of step SL716 in the main CPU 63 in the 91st embodiment).
The specific period corresponds to a specific number (10 times) of the unit period,
The specific calculation means calculates the specific ratio information by using information stored in a plurality of the unit storage areas, and the gaming machine described in any one of the characteristics α11 to α115.

According to the characteristic α116, the predetermined ratio information and the specific ratio information are derived by using the information stored in the common unit period correspondence storage means. Therefore, comparison is made with a configuration in which information used to derive the predetermined ratio information is stored and a configuration in which information used to derive the specific ratio information is stored are provided separately. Then, the storage capacity for storing the information used for deriving the predetermined ratio information and the specific ratio information can be reduced.

Feature αl17. The predetermined calculation means uses the information stored in the plurality of unit storage areas to calculate the predetermined ratio information based on the new storage of the unit target information in the unit period correspondence storage means. Calculate,
The specific calculation means uses the information stored in the plurality of unit storage areas based on that the unit target information is newly stored in the unit period correspondence storage means to obtain the specific ratio information. The gaming machine according to feature α116, which is characterized by being calculated.

According to the characteristic αl17, the predetermined ratio information and the specific ratio information can be updated at the timing when the unit target information is newly stored in the unit period correspondence storage means. Since the update timings of the predetermined ratio information and the specific ratio information are common, the configuration for grasping the update timing of the predetermined ratio information and the specific ratio information is simplified.

Feature αl18. The specific number is a number larger than the predetermined number,
18. The gaming machine according to the characteristic .alpha.16 or .alpha.17, wherein the unit period correspondence storage means is provided with the specific number of the unit storage areas.

According to the feature α18, the specific period information is calculated by using the specific number of unit target information stored in the specific number of unit storage areas provided in the unit period correspondence storage unit. It is possible to simplify the configuration for grasping the unit storage area in which the information used for calculating the specific ratio information is stored in the correspondence storage means. Further, it is possible to grasp the predetermined ratio information in the predetermined period and the specific ratio information in the specific period that is longer than the predetermined period. As a result, when there is an abnormality in the predetermined ratio information and no abnormality in the specific ratio information, and when there is no abnormality in the predetermined ratio information and there is an abnormality in the specific ratio information Also, it is possible to prevent these abnormalities from being overlooked.

In addition, with respect to the configurations of the features α11 to α118, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, and features βA1 to βA. 4. Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αm group>
Features αm1. When a predetermined event (the total number of game balls discharged from the game area PA reaches the unit reference number in the entire game state) as a result of the game, the storage of information corresponding to the predetermined event is stored in the predetermined storage means (first management). The buffer 601, the second management buffer 602, the common management buffer 616, and the common management counter area 621 are executed so that the predetermined information (ball output rate in the unit calculation period) is stored in the predetermined storage means. A predetermined storage execution means (a function of executing the processes of steps SL203 and SL215 in the main CPU 63, a function of executing the process of step SL503 in the main CPU 63, a function of executing the process of step SL703 in the main CPU 63). ,
Using the predetermined information, predetermined mode information corresponding to the result of the game in a predetermined period (the latest four unit calculation periods, the first calculation period) (ball payout rate in the latest four unit calculation periods, A predetermined calculating means for calculating the payout rate in one calculation period (a function for executing the processes of steps SL208 and SL220 in the main CPU 63 in the 89th and 92nd embodiments, and a function in the main CPU 63 in the 90th embodiment). A function of executing the processes of steps SL510 and SL518, a function of executing the processes of steps SL708 and SL716 in the main CPU 63 in the ninety-first embodiment).
Using the predetermined information, the specific mode information (the payout rate in the last 10 unit calculation periods, the second in the unit calculation period for the latest 10 times, the entire second unit calculation period) Specific calculation means for calculating the payout rate in the calculation period (a function of executing the process of step SL220 in the main CPU 63 in the 89th and 92nd embodiments, a process of step SL518 in the main CPU 63 in the 90th embodiment). Function for executing step SL716 in the main CPU 63 in the ninety-first embodiment).
A gaming machine characterized by being equipped with.

According to the feature αm1, it is possible to grasp both the predetermined mode information corresponding to the result of the game in the predetermined period and the specific mode information corresponding to the result of the game in the specific period. Accordingly, when the abnormality of the specific aspect information occurs in the state where the abnormality of the predetermined aspect information has not occurred, it is possible to grasp the abnormality of the specific aspect information. Further, when the abnormality of the predetermined aspect information occurs in a state where the abnormality of the specific aspect information has not occurred, it is possible to grasp the abnormality of the predetermined aspect information.

The predetermined period may be a period until a predetermined time elapses or a period until a predetermined reference trigger is generated. When the predetermined period is a period until the predetermined reference opportunity occurs, the predetermined reference opportunity may be that the total number of used game media reaches the reference number. In this case, the reference number may be one kind or plural kinds. Moreover, the specific period may be a period until a specific time elapses or a period until a specific reference trigger occurs. When the specific period is defined as a period until the specific reference opportunity occurs, the specific reference opportunity may be that the total number of used game media reaches the reference number.

Features αm2. The gaming machine according to feature αm1, wherein a part of the specific period overlaps with at least a part of the predetermined period.

According to the characteristic αm2, it is possible to grasp detailed information about the result of the game in the period in which the predetermined period and the specific period overlap, and the period before and after the period, and the abnormality and the identification of the predetermined mode information in these periods. It is possible to prevent the abnormality of the aspect information from being overlooked.

Features αm3. The predetermined period corresponds to a predetermined number of unit periods (unit calculation period) (four times in the 89th to 92nd embodiments),
The specific period corresponds to a specific number of the unit period (10 times in the 89th to 92nd embodiments),
The predetermined calculation means calculates the predetermined mode information each time the unit period is completed,
The gaming machine described in the feature αm1 or αm2, wherein the specific calculation means calculates the specific mode information every time the unit period is completed.

According to the feature αm3, every time the unit period is completed, the predetermined mode information in the predetermined period that is the predetermined number of unit periods and the specific mode information in the specific period that is the specific number of unit periods are calculated. As a result, it is possible to reduce the possibility that the abnormality of the predetermined mode information in the predetermined period is overlooked, and reduce the possibility that the abnormality of the specific mode information in the specific period is overlooked. Further, since the timing for calculating the predetermined mode information and the timing for calculating the specific mode information are common, the configuration for grasping the timing for calculating the predetermined mode information and the specific mode information can be simplified. ..

Features αm4. The predetermined period corresponds to a predetermined number of unit periods (unit calculation period) (four times in the 89th to 92nd embodiments),
The specific period corresponds to a specific number of the unit period (10 times in the 89th to 92nd embodiments),
The specific number is a number larger than the predetermined number,
The predetermined storage means is a unit storage area (each storage area 601a to 601d of the first management buffer 601) for storing unit target information (ball output rate in the unit calculation period) which is the predetermined information corresponding to the unit period. , Each of the storage areas 602a to 602j of the second management buffer 602, each of the storage areas 616a to 616j of the common management buffer 616, and the payout rate counters 621a to 621j of the common management counter area 621 are equal to or more than the specific number. ,
The predetermined calculation means calculates the predetermined mode information by using information stored in the plurality of unit storage areas,
The gaming machine according to any one of features αm1 to αm3, wherein the specific calculation means calculates the specific aspect information using information stored in a plurality of the unit storage areas.

According to the feature αm4, since the predetermined storage means is provided with the specific number of unit storage areas, which is a number larger than the predetermined number, the predetermined aspect is based on the information stored in the unit storage area of the predetermined storage means. Information and specific aspect information can be calculated. Further, the predetermined mode information and the specific mode information are derived by using the information stored in the common predetermined storage means. Therefore, a configuration in which information used to derive the predetermined aspect information is stored and a configuration in which information used to derive the specific aspect information is stored are separately provided Then, the storage capacity for storing the information used for deriving the predetermined aspect information and the specific aspect information can be reduced.

Features αm5. The predetermined calculation means calculates the predetermined aspect information by using the information stored in the plurality of unit storage areas based on that the unit target information is newly stored in the predetermined storage means. ,
The specific calculation means calculates the specific aspect information by using the information stored in the plurality of unit storage areas based on that the unit target information is newly stored in the predetermined storage means. The gaming machine described in the feature αm4.

According to the feature αm5, the predetermined mode information and the specific mode information are updated at the timing when the unit target information is newly stored in the predetermined storage unit. Since the predetermined aspect information and the specific aspect information have the same update timing, the configuration for grasping the update timing of the predetermined aspect information and the specific aspect information can be simplified. Further, it is possible to prevent the abnormality of the predetermined aspect information and the abnormality of the specific aspect information from being overlooked by updating the predetermined aspect information and the specific aspect information in a period shorter than the predetermined period and the specific period.

Features αm6. The predetermined calculation means includes the unit storage area in which the latest unit target information is stored, including the unit storage area, and the predetermined number of the unit storage areas that are continuous with the unit period corresponding to the latest unit target information as a reference. The gaming machine according to feature αm4 or αm5, wherein the predetermined aspect information is calculated by using the unit target information stored in.

According to the characteristic αm6, the unit target information stored in a predetermined number of unit storage areas consecutive from the unit storage area of the number larger than the predetermined number based on the unit period corresponding to the latest unit target information is used. Then, the predetermined aspect information can be calculated. The storage capacity for storing the unit target information can be reduced as compared with a configuration in which another storage unit having a predetermined number of unit storage areas for calculating the predetermined mode information is provided.

Features αm7. The unit storage areas in which the unit target information is stored in the plurality of unit storage areas are configured to be sequentially changed in a predetermined order,
The gaming machine is a storage target storage unit (first write pointer 603) that stores information that enables specification of the type of the unit storage area that is a target for storing the next unit target information among the plurality of unit storage areas. , A second write pointer 604, a common write pointer 617),
The gaming machine according to feature αm6, wherein the predetermined calculation unit specifies the unit storage area in which the most recent unit target information is stored based on the information stored in the storage target storage unit.

According to the feature αm7, the most recent unit target is stored by using the storage target storage unit provided to specify the type of the unit storage region that is the target of storing the next unit target information among the plurality of unit storage regions. A unit storage area in which information is stored is specified. Therefore, it is possible to specify the unit storage area in which the latest unit target information is stored, without the need for a dedicated configuration for specifying the unit storage area in which the latest unit target information is stored.

Features αm8. The gaming machine according to any one of features αm4 to αm7, wherein the predetermined storage unit includes the unit storage area in the specific number.

According to the characteristic αm8, the predetermined storage means is provided with the specific number of unit storage areas, and thus the predetermined mode information is calculated using the unit target information stored in the predetermined number of unit storage areas smaller than the specific number. In addition, the specific aspect information can be calculated by using the unit target information stored in the specific number of unit storage areas. A unit used for calculating the specific aspect information by matching the number of unit target information used for calculating the specific aspect information with the number of unit storage areas provided in the predetermined storage means. It is possible to simplify the processing for specifying the unit storage area in which the target information is stored.

Features αm9. A game is played using a game medium,
This gaming machine is based on the occurrence of a profit-giving event (entering a game ball into the general winning opening 31, the special electricity winning device 32, the first working opening 33, and the second working opening 34) as the game is played. And a profit giving means (a function of executing the processes of steps S316 and S317 in the main CPU 63).
The predetermined storage execution means is for causing the predetermined storage means to execute the storage of information corresponding to the profit being given as the predetermined event,
The predetermined aspect information is predetermined ratio information corresponding to the ratio of the total amount of the profits given in the predetermined period to the total number of the game media used in the predetermined period (in the entire unit calculation period for the latest four times). The payout rate, the payout rate in the first calculation period),
The specific aspect information is specific ratio information corresponding to the ratio of the total amount of the profit given in the specific period to the total number of the game media used in the specific period (in the entire unit calculation period for the last 10 times). The payout rate, the payout rate in the second calculation period), The gaming machine according to any one of the features αm1 to αm8.

According to the characteristic αm9, based on the predetermined ratio information, it is possible to grasp the ratio of the total amount of profits given in the predetermined period to the total number of game media used in the predetermined period, and the specific ratio information. Based on the above, it is possible to grasp the ratio of the total amount of profits given in the specific period to the total number of game media used in the specific period. By making it possible to grasp the predetermined ratio information, the ratio of the total amount of profits given in the predetermined period to the total number of game media used in the predetermined period becomes unnaturally high. It is possible to grasp the abnormality that becomes low. Further, by making it possible to grasp the specific ratio information, the ratio of the total amount of profits given in the specific period to the total number of game media used in the specific period becomes unnaturally high. It is possible to grasp an abnormality that is lowered to a certain degree.

Features αm10. Utilization measuring means for measuring the total number of the used game media (function of executing the processes of steps SL102 and SL103 in the main CPU 63),
An award measurement means (a function of executing the process of step SL103 in the main CPU 63) for measuring the total amount of the award given.
Equipped with
The predetermined information includes information corresponding to the total amount of the profit measured by the imparting measuring unit,
The predetermined calculation means calculates the predetermined ratio information by using information (total payout number of game balls) corresponding to the total amount of the profit measured by the addition measurement means,
The specific calculation means calculates the specific ratio information by using information (total payout number of game balls) corresponding to the total amount of the profit measured by the addition measuring means,
As a game state, a first game state (a game state that is neither the open/close execution mode nor the high frequency support mode) and a second game state (a game that is the open/close execution mode) in which the expected value of the profit to be given is different State, game state that is a high frequency support mode) exists,
The usage measuring means measures the total number of the game media used without distinguishing the first gaming state and the second gaming state,
The gaming machine according to feature αm9, wherein the grant measuring means measures the total amount of the granted profit without distinguishing between the first gaming state and the second gaming state.

According to the characteristic αm10, the predetermined ratio information and the specific ratio information are calculated by using the information corresponding to the total amount of the added profits measured without distinguishing the first gaming state and the second gaming state. .. Therefore, based on the predetermined ratio information and the specific ratio information, the abnormality in the ratio of the total amount of the profits provided to the total number of the game media used in the first game state, and the game used in the second game state It is possible to grasp the abnormality of the ratio of the total amount of profits given to the total number of media. By making it possible to grasp both the predetermined ratio information and the specific ratio information, it is possible to prevent these abnormalities from being overlooked. Further, a configuration for measuring the total number of game media used in the first game state and a configuration for measuring the total number of game media used in the second game state are separately provided. As compared with the configuration, the configuration for measuring the total number of used game media can be simplified. Further, in comparison with a configuration in which a configuration for measuring the total amount of profit in the first gaming state and a configuration for measuring the total amount of profit in the second gaming state are separately provided, The configuration for measuring the total amount can be simplified.

Features αm11. A game area (game area PA) in which game balls flow down as the game medium,
Predetermined ball entering means (general winning opening 31, special electric winning device 32, first operating port 33, second operating port 34) into which a game ball flowing down in the game area can enter.
Predetermined detection means (first winning opening detection sensor 42a, second winning opening detection sensor 43a, third winning opening detection sensor 44a, special electricity detection sensor 45a, first operation) for detecting a game ball that has entered the predetermined entering means. A mouth detecting sensor 46a, a second working mouth detecting sensor 47a),
Specific storage execution means (a function of executing the process of step SL102 in the main CPU 63) that causes the corresponding storage information to be stored in the specific storage means based on the fact that the game ball is detected by the predetermined detection means. ,
Equipped with
The profit granting means stores a predetermined number of game balls as a grant of the profit based on the fact that the information corresponding to the detection of the game ball being detected by the predetermined detecting means is stored in the specific storage means. Processing for allowing the person to be given (the processing of steps S316 and S317 in the main CPU 63),
The gaming machine is provided with a plurality of ball entry means including the predetermined ball entry means as ball entry means capable of entering a game ball flowing down through the game area and discharging the entered game ball from the game area. (Outward opening 24a, general winning opening 31, special electric winning device 32, first operating port 33, second operating port 34),
A game ball flowing down the game area is discharged from the game area by entering any of the plurality of ball entering means.
As a detecting means for detecting a game ball entering any of the plurality of ball entering means, a plurality of detecting means including the predetermined detecting means (first winning opening detecting sensor 42a, second winning opening detecting sensor 43a, The third winning opening detection sensor 44a, the special electricity detection sensor 45a, the first working opening detection sensor 46a, the second working opening detection sensor 47a, the out opening detection sensor 48a),
The game ball entered in any one of the plurality of ball entering means is configured to be detected by any of the plurality of detecting means,
The predetermined calculation means calculates, as the predetermined ratio information, information corresponding to the ratio of the total number of game balls provided to the total number of game balls discharged from the game area in the predetermined period,
The specific calculation means calculates, as the specific ratio information, information corresponding to the ratio of the total number of provided game balls to the total number of discharged game balls discharged from the game area in the specific period. The gaming machine described in αm9 or αm10.

According to the feature αm11, the game ball flowing down the game area is discharged from the game area by entering one of the plurality of ball entering means, and also enters one of the plurality of ball entering means. The game sphere played is configured to be detected by any of a plurality of detecting means. Therefore, it is possible to measure all the game balls discharged from the game area. The predetermined ratio information is information corresponding to the ratio of the total number of provided game balls to the total discharged number of game balls discharged from the game area in a predetermined period. Therefore, by making it possible to grasp the predetermined ratio information, the ratio of the total granted number of game balls to the total discharged number of game balls discharged from the game area during the predetermined period is abnormally high, and the game during the predetermined period It is possible to grasp an abnormality in which the ratio of the total number of game balls given to the total number of game balls discharged from the area is unnaturally low. Further, the specific ratio information is information corresponding to the ratio of the total number of provided game balls to the total number of discharged game balls discharged from the game area in the specific period. Therefore, by making it possible to grasp the specific ratio information, the ratio of the total number of game balls given to the total number of discharged game balls discharged from the game area during the specific period is abnormally high, and the game during the specific period It is possible to grasp an abnormality in which the ratio of the total number of game balls given to the total number of game balls discharged from the area is unnaturally low. By making it possible to grasp the predetermined ratio information and the specific ratio information, it is possible to prevent the abnormality of the ratio of the total number of game balls given to the total number of discharged game balls from the game area being overlooked. ..

For the configurations of the features αm1 to αm11, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, and features βA1 to βA. 4. Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αn group>
Features αn1. When a predetermined event (the total number of game balls discharged from the game area PA reaches the unit reference number in the entire game state) as a result of the game, the storage of information corresponding to the predetermined event is stored in the predetermined storage means (first management). The buffer 601, the second management buffer 602, the common management buffer 616, and the common management counter area 621 are executed so that the predetermined information (ball output rate in the unit calculation period) is stored in the predetermined storage means. A predetermined storage execution means (a function of executing the processes of steps SL203 and SL215 in the main CPU 63, a function of executing the process of step SL503 in the main CPU 63, a function of executing the process of step SL703 in the main CPU 63). ,
Using the predetermined information, predetermined mode information corresponding to the result of the game in a predetermined period (the latest four unit calculation periods, the first calculation period) (ball payout rate in the latest four unit calculation periods, A predetermined calculating means for calculating the payout rate in one calculation period (a function for executing the processes of steps SL208 and SL220 in the main CPU 63 in the 89th and 92nd embodiments, and a function in the main CPU 63 in the 90th embodiment). A function of executing the processes of steps SL510 and SL518, a function of executing the processes of steps SL708 and SL716 in the main CPU 63 in the ninety-first embodiment).
Equipped with
The predetermined period corresponds to a predetermined number of unit periods (unit calculation period) (four times in the 89th to 92nd embodiments),
The game machine characterized in that the predetermined calculation means calculates the predetermined mode information every time the unit period is completed.

According to the characteristic αn1, it is possible to grasp the information corresponding to the result of the game in the predetermined period based on the predetermined mode information. Therefore, by making it possible to grasp the predetermined mode information, it is possible to grasp the abnormality of the information corresponding to the result of the game in the predetermined period. Further, the predetermined aspect information can be updated at intervals shorter than the predetermined period. If the predetermined mode information is updated every time the predetermined period ends, the game in the period from the latter half of the front side (first) predetermined period to the first half of the rear side (second) predetermined period Even if an abnormality occurs in the information corresponding to the result, it is possible that the abnormality cannot be found based on the predetermined aspect information in the front predetermined period and the predetermined aspect information in the rear predetermined period. On the other hand, with the configuration in which the predetermined mode information is updated at intervals shorter than the predetermined period, it is possible to reduce the possibility that the abnormality of the information corresponding to the result of the game in the predetermined period is overlooked.

Features αn2. First predetermined aspect storage means (first unit update area 606a, second unit update area 607a) that stores the predetermined aspect information calculated by the predetermined calculation means when the unit period is completed,
Second predetermined mode storage means (the latest area 606b of the first calculation period, the nearest area 607b of the second calculation period) that stores the predetermined mode information calculated by the predetermined calculation means when the predetermined period is completed;
Means for executing notification for making each of the predetermined mode information stored in the first predetermined mode storage means and the predetermined mode information stored in the second predetermined mode storage means recognizable (main side A function of executing the processing of step SL312 in the CPU 63),
The gaming machine according to the feature αn1.

According to the characteristic αn2, when the unit period is completed, the predetermined mode information calculated by the predetermined calculation means can be grasped, so that when the abnormality of the predetermined mode information occurs, the abnormality can be grasped early. be able to. As a result, the manager of the game hall can take prompt action against the abnormality. Further, by making it possible to grasp the predetermined mode information calculated by the predetermined calculation means when the predetermined period is completed, it is possible to monitor the predetermined mode information for each predetermined period.

Features αn3. Means for storing the predetermined aspect information in the predetermined period calculated by the predetermined calculating means at a predetermined timing (first history area 606c in the first calculation period, second history area 606d in the first calculation period, second calculation A first history area 607c of a period, a second history area 607d of a second calculation period),
Means for storing the predetermined aspect information in the predetermined period started by the completion of the predetermined period which is the calculation target at the predetermined timing (the area closest to the first calculation period 606b, the first calculation period first area 606b). A history area 606c, a latest area 607b of the second calculation period, a first history area 607c of the second calculation period),
The gaming machine according to the feature αn1 or αn2.

According to the feature αn3, the history of the predetermined mode information can be stored and grasped at predetermined time intervals. By making it possible to grasp the past predetermined mode information, it is possible to reduce the frequency with which the manager of the game hall confirms the predetermined mode information, and reduce the monitoring load on the predetermined mode information by the game hall manager. Further, when the abnormality of the predetermined mode information is detected, it is possible to trace back from a time when the abnormality has occurred, in a past manner.

In the configuration including the feature αn1 and calculating the predetermined mode information each time the unit period ends, the predetermined mode information is stored when the interval of storing the history of the predetermined mode information is a predetermined period interval longer than the unit period. It is possible to grasp predetermined aspect information in a wide range while suppressing an increase in the number of aspect information.

Features αn4. The predetermined storage means is a unit storage area (each storage area 601a to 601d of the first management buffer 601) for storing unit target information (ball output rate in the unit calculation period) which is the predetermined information corresponding to the unit period. , The storage areas 602a to 602j of the second management buffer 602, the storage areas 616a to 616j of the common management buffer 616, and the payout rate counters 621a to 621j of the common management counter area 621. ,
The predetermined calculation means calculates the predetermined aspect information by using the information stored in the plurality of unit storage areas based on that the unit target information is newly stored in the predetermined storage means. The gaming machine according to any one of the features αn1 to αn3.

According to the feature αn4, the predetermined mode information can be updated in a period shorter than the predetermined period. If the predetermined mode information is updated every time the predetermined period ends, the game in the period from the latter half of the front side (first) predetermined period to the first half of the rear side (second) predetermined period Even if an abnormality occurs in the information corresponding to the result, it is possible that the abnormality cannot be found based on the predetermined aspect information in the front predetermined period and the predetermined aspect information in the rear predetermined period. On the other hand, with the configuration in which the predetermined mode information is updated at intervals shorter than the predetermined period, it is possible to reduce the possibility that the abnormality of the information corresponding to the result of the game in the predetermined period is overlooked.

Features αn5. The predetermined calculation means includes the unit storage area in which the latest unit target information is stored, including the unit storage area, and the predetermined number of the unit storage areas that are continuous with the unit period corresponding to the latest unit target information as a reference. The gaming machine according to feature αn4, wherein the predetermined mode information is calculated using the unit target information stored in.

According to the characteristic αn5, the unit target information stored in a predetermined number of unit storage areas consecutive from the unit storage area of the number larger than the predetermined number based on the unit period corresponding to the latest unit target information is used. Then, the predetermined aspect information can be calculated. The storage capacity for storing the unit target information can be reduced as compared with a configuration in which another storage unit having a predetermined number of unit storage areas for calculating the predetermined mode information is provided.

Features αn6. The unit storage area that is a target for storing the unit target information in the plurality of unit storage areas is configured to be sequentially changed in a predetermined order,
The gaming machine is a storage target storage unit (first write pointer 603) that stores information that enables specification of the type of the unit storage area that is a target for storing the next unit target information among the plurality of unit storage areas. , A second write pointer 604, a common write pointer 617),
The gaming machine according to feature αn5, wherein the predetermined calculation unit specifies the unit storage area in which the latest unit target information is stored based on information stored in the storage target storage unit.

According to the feature αn6, the most recent unit target is stored by using the storage target storage unit provided to specify the type of the unit storage area that is the target of storing the next unit target information among the plurality of unit storage areas. A unit storage area in which information is stored is specified. Therefore, it is possible to specify the unit storage area in which the latest unit target information is stored, without the need for a dedicated configuration for specifying the unit storage area in which the latest unit target information is stored.

Features αn7. A game is played using a game medium (game ball).
This gaming machine is based on the occurrence of a profit-giving event (entering a game ball into the general winning opening 31, the special electricity winning device 32, the first working opening 33, and the second working opening 34) as the game is played. And a profit giving means (a function of executing the processes of steps S316 and S317 in the main CPU 63).
The predetermined storage execution means is for causing the predetermined storage means to execute the storage of information corresponding to the profit being given as the predetermined event,
The predetermined aspect information is predetermined ratio information corresponding to the ratio of the total amount of the profits given in the predetermined period to the total number of the game media used in the predetermined period (in the entire unit calculation period for the latest four times). The payout rate, the payout rate in the first calculation period), The gaming machine according to any one of the features αn1 to αn6.

According to the characteristic αn7, it is possible to grasp the ratio of the total amount of profits given in the predetermined period to the total number of game media used in the predetermined period based on the predetermined ratio information. By making it possible to grasp the predetermined ratio information, the total amount of profits given in the predetermined period with respect to the total number of game media used in the predetermined period becomes abnormally high, and it is used in the predetermined period. It is possible to grasp an anomaly in which the total amount of profits given in the predetermined period with respect to the total number of game media is unnaturally low.

Features αn8. Utilization measuring means for measuring the total number of the used game media (function of executing the processes of steps SL102 and SL103 in the main CPU 63),
An award measurement means (a function of executing the process of step SL103 in the main CPU 63) for measuring the total amount of the award given.
Equipped with
The predetermined information includes information corresponding to the total amount of the profit measured by the imparting measuring unit,
The predetermined calculation means calculates the predetermined ratio information by using information (total payout number of game balls) corresponding to the total amount of the profit measured by the addition measurement means,
As a game state, a first game state (a game state that is neither the open/close execution mode nor the high frequency support mode) and a second game state (a game that is the open/close execution mode) in which the expected value of the profit to be given is different State, game state that is a high frequency support mode) exists,
The usage measuring means measures the total number of the game media used without distinguishing the first gaming state and the second gaming state,
The gaming machine according to feature αn7, characterized in that the grant measuring means measures the total amount of the profit without distinguishing between the first gaming state and the second gaming state.

According to the characteristic αn8, the predetermined ratio information is calculated by using information corresponding to the total amount of profit measured without distinguishing the first gaming state and the second gaming state. Therefore, based on the predetermined ratio information, an abnormality in the ratio of the total amount of profits given to the total number of game media used in the first game state, and the total number of game media used in the second game state It is possible to grasp the anomaly in the ratio of the total amount of profit given to the. A structure for measuring the total number of game media used in the first game state and a structure for separately measuring the total number of game media used in the second game state are provided separately. By comparison, the configuration for measuring the total number of used game media can be simplified. Further, in comparison with a configuration in which a configuration for measuring the total amount of profit in the first gaming state and a configuration for measuring the total amount of profit in the second gaming state are separately provided, The configuration for measuring the total amount can be simplified.

Features αn9. A game area (game area PA) in which game balls flow down as the game medium,
Predetermined ball entering means (general winning opening 31, special electric winning device 32, first operating port 33, second operating port 34) into which a game ball flowing down in the game area can enter.
Predetermined detection means (first winning opening detection sensor 42a, second winning opening detection sensor 43a, third winning opening detection sensor 44a, special electricity detection sensor 45a, first operation) for detecting a game ball that has entered the predetermined entering means. A mouth detecting sensor 46a, a second working mouth detecting sensor 47a),
Specific storage execution means (a function of executing the process of step SL102 in the main CPU 63) that causes the corresponding storage information to be stored in the specific storage means based on the fact that the game ball is detected by the predetermined detection means. ,
Equipped with
The profit granting means stores a predetermined number of game balls as a grant of the profit based on the fact that the information corresponding to the detection of the game ball being detected by the predetermined detecting means is stored in the specific storage means. Processing for allowing the person to be given (the processing of steps S316 and S317 in the main CPU 63),
The gaming machine is provided with a plurality of ball entry means including the predetermined ball entry means as ball entry means capable of entering a game ball flowing down through the game area and discharging the entered game ball from the game area. (Outward opening 24a, general winning opening 31, special electric winning device 32, first operating port 33, second operating port 34),
A game ball flowing down the game area is discharged from the game area by entering any of the plurality of ball entering means.
As a detecting means for detecting a game ball entering any of the plurality of ball entering means, a plurality of detecting means including the predetermined detecting means (first winning opening detecting sensor 42a, second winning opening detecting sensor 43a, The third winning opening detection sensor 44a, the special electricity detection sensor 45a, the first working opening detection sensor 46a, the second working opening detection sensor 47a, the out opening detection sensor 48a),
The game ball entered in any one of the plurality of ball entering means is configured to be detected by any of the plurality of detecting means,
The predetermined calculating means calculates, as the predetermined ratio information, information corresponding to a ratio of the total number of game balls to be provided to the total number of game balls discharged from the game area in the predetermined period. The gaming machine described in αn7 or αn8.

According to the characteristic αn9, the game ball flowing down the game area is discharged from the game area by entering one of the plurality of ball entering means, and also enters one of the plurality of ball entering means. The game sphere played is configured to be detected by any of a plurality of detecting means. Therefore, it is possible to measure all the game balls discharged from the game area. Further, the predetermined ratio information is information corresponding to the ratio of the total number of game balls provided to the total number of discharged game balls in the predetermined period. Therefore, by making it possible to grasp the predetermined ratio information, the ratio of the total granted number of game balls to the total discharged number of game balls discharged from the game area during the predetermined period is abnormally high, and the game during the predetermined period It is possible to grasp an abnormality in which the ratio of the total number of game balls given to the total number of game balls discharged from the area is unnaturally low.

In addition, with respect to the configurations of the features αn1 to αn9, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αo group>
Features αo1. When a predetermined event (the total number of game balls discharged from the game area PA reaches the unit reference number in the entire game state) as a result of the game, the storage of information corresponding to the predetermined event is stored in the predetermined storage means (first management). Predetermined storage execution means for causing the predetermined information (ball output rate in the unit calculation period) to be stored in the predetermined storage means by being executed in the buffer 601, the common management buffer 616, and the common management counter area 621). (A function of the main CPU 63 to execute the process of step SL203, a function of the main CPU 63 to execute the process of step SL503, a function of the main CPU 63 to execute the process of step SL703),
Using the predetermined information, predetermined mode information corresponding to the result of the game in a predetermined period (the latest four unit calculation periods, the first calculation period) (ball payout rate in the latest four unit calculation periods, A predetermined calculating means for calculating the payout rate in one calculation period (a function for executing the processes of steps SL208 and SL220 in the main CPU 63 in the 89th and 92nd embodiments, and a function in the main CPU 63 in the 90th embodiment). A function of executing the processes of steps SL510 and SL518, a function of executing the processes of steps SL708 and SL716 in the main CPU 63 in the ninety-first embodiment).
Equipped with
The predetermined period corresponds to a predetermined number of unit periods (unit calculation period) (four times in the 89th to 92nd embodiments),
The predetermined storage means is a unit storage area (each storage area 601a to 601d of the first management buffer 601) for storing unit target information (ball output rate in the unit calculation period) which is the predetermined information corresponding to the unit period. , The storage areas 602a to 602j of the second management buffer 602, the storage areas 616a to 616j of the common management buffer 616, and the payout rate counters 621a to 621j of the common management counter area 621. ,
A game machine characterized in that the predetermined calculation means calculates the predetermined mode information by using information stored in the predetermined number of unit storage areas.

According to the characteristic αo1, it is possible to grasp the information corresponding to the result of the game in the predetermined period based on the predetermined mode information. By making it possible to grasp the predetermined mode information, it is possible to grasp the abnormality of the information corresponding to the result of the game in the predetermined period. Since the predetermined storage means is provided with a specific number of unit storage areas, which is a number larger than the predetermined number, the predetermined mode information can be calculated based on the information stored in the unit storage areas of the predetermined storage means. it can. Further, the predetermined mode information is calculated using a plurality of unit object information stored in the predetermined storage means. Therefore, it is possible to finely update the information used for calculating the predetermined mode information, as compared with the configuration in which the predetermined mode information is calculated using one piece of information.

Features αo2. The number of the unit storage areas is larger than the predetermined number,
The predetermined calculation unit includes the unit storage area in which the latest unit target information is stored, including the unit storage area, and the unit storage area corresponding to the predetermined number of the unit storage areas corresponding to the latest unit target information. The gaming machine according to feature αo1, wherein the predetermined aspect information is calculated using the unit target information stored in.

According to the characteristic αo2, the unit target information stored in a predetermined number of unit storage areas consecutive from the unit storage area of the number larger than the predetermined number based on the unit period corresponding to the latest unit target information is used. Then, the predetermined aspect information can be calculated. The storage capacity for storing the unit target information can be reduced as compared with a configuration in which another storage unit having a predetermined number of unit storage areas for calculating the predetermined mode information is provided.

Features αo3. The unit storage areas in which the unit target information is stored in the plurality of unit storage areas are configured to be sequentially changed in a predetermined order,
The gaming machine is a storage target storage unit (first write pointer 603) that stores information that enables specification of the type of the unit storage area that is a target for storing the next unit target information among the plurality of unit storage areas. , A second write pointer 604, a common write pointer 617),
The gaming machine according to feature αo2, wherein the predetermined calculation unit specifies the unit storage area in which the most recent unit target information is stored, based on information stored in the storage target storage unit.

According to the characteristic αo3, the most recent unit target is stored by using the storage target storage unit provided for specifying the type of the unit storage area that is the target of storing the next unit target information among the plurality of unit storage areas. A unit storage area in which information is stored is specified. Therefore, it is possible to specify the unit storage area in which the latest unit target information is stored, without the need to provide a dedicated configuration for specifying the unit storage area in which the latest unit target information is stored.

Features αo4. A game is played using a game medium (game ball).
This gaming machine is based on the occurrence of a profit-giving event (entering a game ball into the general winning opening 31, the special electricity winning device 32, the first working opening 33, and the second working opening 34) as the game is played. And a profit giving means (a function of executing the processes of steps S316 and S317 in the main CPU 63).
The predetermined storage execution means is for causing the predetermined storage means to execute the storage of information corresponding to the profit being given as the predetermined event,
The predetermined aspect information is predetermined ratio information corresponding to the ratio of the total amount of the profits given in the predetermined period to the total number of the game media used in the predetermined period (in the entire unit calculation period for the latest four times). The payout rate, the payout rate in the first calculation period). The gaming machine according to any one of the features αo1 to αo3.

According to the characteristic αo4, based on the predetermined ratio information, it is possible to grasp the ratio of the total amount of profits given in the predetermined period to the total number of game media used in the predetermined period. By making it possible to grasp the predetermined ratio information, the ratio of the total amount of profits given in the predetermined period to the total number of game media used in the predetermined period becomes unnaturally high, and the unnatural degree It is possible to grasp abnormalities that become extremely low.

Features αo5. Utilization measuring means for measuring the total number of the used game media (function of executing the processes of steps SL102 and SL103 in the main CPU 63),
An award measurement means (a function of executing the process of step SL103 in the main CPU 63) for measuring the total amount of the award given.
Equipped with
The predetermined information includes information corresponding to the total amount of the profit measured by the imparting measuring unit,
The predetermined calculation means calculates the predetermined ratio information by using information (total payout number of game balls) corresponding to the total amount of the profit measured by the addition measurement means,
As a game state, a first game state (a game state that is neither the open/close execution mode nor the high frequency support mode) and a second game state (a game that is the open/close execution mode) in which the expected value of the profit to be given is different State, game state that is a high frequency support mode) exists,
The usage measuring means measures the total number of the game media used without distinguishing the first gaming state and the second gaming state,
The gaming machine according to feature αo4, wherein the grant measuring unit measures the total amount of the profit without distinguishing between the first gaming state and the second gaming state.

According to the characteristic αo5, the predetermined ratio information is calculated by using information corresponding to the total amount of profit measured without distinguishing the first gaming state and the second gaming state. Therefore, based on the predetermined ratio information, an abnormality in the ratio of the total amount of profits given to the total number of game media used in the first game state, and the total number of game media used in the second game state It is possible to grasp the anomaly in the ratio of the total amount of profit given to the. A structure for measuring the total number of game media used in the first game state and a structure for separately measuring the total number of game media used in the second game state are provided separately. By comparison, the configuration for measuring the total number of used game media can be simplified. Further, in comparison with a configuration in which a configuration for measuring the total amount of profit in the first gaming state and a configuration for measuring the total amount of profit in the second gaming state are separately provided, The configuration for measuring the total amount can be simplified.

Features αo6. A game area (game area PA) in which game balls flow down as the game medium,
Predetermined ball entering means (general winning opening 31, special electric winning device 32, first operating port 33, second operating port 34) into which a game ball flowing down in the game area can enter.
Predetermined detection means (first winning opening detection sensor 42a, second winning opening detection sensor 43a, third winning opening detection sensor 44a, special electricity detection sensor 45a, first operation) for detecting a game ball that has entered the predetermined entering means. A mouth detecting sensor 46a, a second working mouth detecting sensor 47a),
Specific storage execution means (a function of executing the process of step SL102 in the main CPU 63) that causes the corresponding storage information to be stored in the specific storage means based on the fact that the game ball is detected by the predetermined detection means. ,
Equipped with
The profit granting means stores a predetermined number of game balls as a grant of the profit based on the fact that the information corresponding to the detection of the game ball being detected by the predetermined detecting means is stored in the specific storage means. Processing for allowing the person to be given (the processing of steps S316 and S317 in the main CPU 63),
The gaming machine is provided with a plurality of ball entry means including the predetermined ball entry means as ball entry means capable of entering a game ball flowing down through the game area and discharging the entered game ball from the game area. (Outward opening 24a, general winning opening 31, special electric winning device 32, first operating port 33, second operating port 34),
A game ball flowing down the game area is discharged from the game area by entering any of the plurality of ball entering means.
As a detecting means for detecting a game ball entering any of the plurality of ball entering means, a plurality of detecting means including the predetermined detecting means (first winning opening detecting sensor 42a, second winning opening detecting sensor 43a, The third winning opening detection sensor 44a, the special electricity detection sensor 45a, the first working opening detection sensor 46a, the second working opening detection sensor 47a, the out opening detection sensor 48a),
The game ball entered in any one of the plurality of ball entering means is configured to be detected by any of the plurality of detecting means,
The predetermined calculating means calculates, as the predetermined ratio information, information corresponding to a ratio of the total number of game balls to be provided to the total number of game balls discharged from the game area in the predetermined period. The gaming machine described in αo4 or αo5.

According to the characteristic αo6, the game ball flowing down the game area is discharged from the game area by entering one of the plurality of ball entering means, and also enters one of the plurality of ball entering means. The game sphere played is configured to be detected by any of a plurality of detecting means. Therefore, it is possible to measure all the game balls discharged from the game area. Further, the predetermined ratio information is information corresponding to the ratio of the total number of game balls provided to the total number of discharged game balls in the predetermined period. Therefore, by making it possible to grasp the predetermined ratio information, the ratio of the total granted number of game balls to the total discharged number of game balls discharged from the game area during the predetermined period is abnormally high, and the game during the predetermined period It is possible to grasp an abnormality in which the ratio of the total number of game balls given to the total number of game balls discharged from the area is unnaturally low.

In addition, with respect to the configurations of the features αo1 to αo6, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the inventions related to the characteristic α1 group, the characteristic αm group, the characteristic αn group, and the characteristic αo group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, in a pachinko machine, the game machine front face section is provided with a dish storage section for storing the game balls given to the player, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, it is necessary to manage the gaming machine appropriately, and there is still room for improvement in this respect.

<Characteristic αp group>
Features αp1. A predetermined storage unit (common management buffer 616) having a plurality of unit storage areas (0th to 9th storage areas 616a to 616j of the common management buffer 616) for storing the unit target information (ball output rate in the unit calculation period). ,
Unit storage for storing the unit target information in the unit storage area based on the occurrence of a storage execution trigger (the total number of game balls discharged from the game area PA in all game states reaches the unit reference number) Executing means (function of executing the process of step SL503 in the main CPU 63);
Equipped with
The unit storage areas in which the unit target information is stored in the plurality of unit storage areas are configured to be sequentially changed in a predetermined order,
This gaming machine is
A storage target storage unit (common write pointer 617) that stores information that enables specification of the type of the unit storage area that is a target for storing the next unit target information among the plurality of unit storage areas;
A plurality of the unit storage areas, which are some of the unit storage areas, and are determined based on the unit storage areas corresponding to the information stored in the storage target storage unit. First predetermined process executing means for executing the first predetermined process using the stored unit target information (function of executing the processes of steps SL601 to SL609 in the main CPU 63);
A gaming machine characterized by being equipped with.

According to the characteristic αp1, since the unit storage areas in which the unit target information is stored in the plurality of unit storage areas are sequentially changed in a predetermined order, they are already stored in the plurality of unit storage areas. New unit object information can be stored without shifting existing unit object information. Further, in the case where the first predetermined process is executed by using the storage target storage means provided for specifying the type of the unit storage area for which the next unit target information is to be stored among the plurality of unit storage areas A part of the unit storage area in which the unit target information to be used for is stored is determined. For this reason, while eliminating the need to provide a dedicated configuration for determining a part of the unit storage area in which the unit target information used when executing the first predetermined process is provided separately from the storage target storage means. It is possible to determine a part of the unit storage area in which the unit target information used when executing the first predetermined process is stored.

Feature αp2. The first predetermined process execution means is configured to continuously connect the unit storage area corresponding to the information stored in the storage target storage means and the unit storage area continuous from the unit storage area in an order opposite to the predetermined order. The gaming machine according to feature αp1, wherein the first predetermined process is executed by using the unit target information stored in a plurality of the unit storage regions including a region.

According to the characteristic αp2, a plurality of units including a unit storage area corresponding to the information stored in the storage target storage unit and a unit storage area continuous in the order opposite to the predetermined order from the unit storage area. Since the first predetermined process is executed using the unit target information stored in the storage area, it is dedicated for specifying the unit storage area in which a plurality of the latest consecutive unit target information is stored. It becomes possible to execute the first predetermined process based on a plurality of the latest continuous unit object information without requiring the configuration of.

Features αp3. It is provided with a second predetermined processing execution means (a function of executing the processing of step SL518 in the main CPU 63) that executes the second predetermined processing by using all the information of the plurality of unit storage areas in the predetermined storage means. The gaming machine according to the feature αp1 or αp2.

According to the characteristic αp3, since the second predetermined process is executed by using all the information of the plurality of unit storage areas in the predetermined storage unit, the information used for the second predetermined process is stored in the predetermined storage unit. It is possible to simplify the processing configuration for identifying the unit storage area in which it is stored.

In addition, with respect to the configurations of the features αp1 to αp3, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the above characteristic αp group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, in a pachinko machine, the game machine front face section is provided with a dish storage section for storing the game balls given to the player, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as exemplified above, there is a demand for a configuration capable of suitably executing the processing for the predetermined storage means, and there is still room for improvement in this respect.

<Characteristic αq group>
Feature αq1. Predetermined profit based on the occurrence of a predetermined profit-giving event (general winning port 31, special electric prize winning device 32, first operating port 33, second operating port 34 entering the game ball) due to the game being played A predetermined profit giving means (a function of executing the processes of steps S316 and S317 in the main CPU 63);
Calculating specific event information (total number data in the 93rd to 96th embodiments) corresponding to the number of times a specific event (a game ball is ejected from the game area PA) due to the execution of a game 1 calculation means (function of executing the processing of step SM306 of the main CPU 63 in the 93rd to 96th embodiments);
Second calculating means for calculating predetermined ratio information (base value) corresponding to the ratio of the total amount of the predetermined profit to the specific event information (steps SN101 to SN104 of the main CPU 63 in the 93rd to 96th embodiments). Function to execute processing),
A predetermined notification means (function of executing the processing of steps SM511 to SM513 of the main CPU 63 in the 93rd to 96th embodiments) for notifying the predetermined ratio information calculated by the second calculation means;
A specific notifying means for notifying the specific event information calculated by the first calculating means (function of executing the processing of steps SM601 to SM605 of the main CPU 63 in the 93rd to 96th embodiments);
A gaming machine characterized by being equipped with.

According to the characteristic αq1, it is possible to grasp based on the notification of the predetermined ratio information whether or not the predetermined ratio information is within the theoretical value range of the predetermined ratio information. Further, when the number of occurrences of the specific event that is grasped based on the notification of the specific event information is large, it can be possible to grasp that the degree of convergence of the predetermined ratio information is high, and the notification of the specific event information is performed. When the number of occurrences of the specific event grasped based on the number is small, it can be grasped that the degree of convergence of the predetermined ratio information is low. As described above, it is possible to suitably monitor the predetermined ratio information, and it is possible to suitably manage the gaming machine.

Feature αq2. A game is played using a game medium (game ball).
The first calculation means calculates information (total number data in the 93rd to 96th embodiments) corresponding to the total number of used game media as the specific event information, in the characteristic αq1. Game machine.

According to the characteristic αq2, the degree of convergence of the predetermined ratio information is obtained by providing the configuration of the characteristic αq1 and making it possible to grasp the information corresponding to the total number of game media used based on the notification of the specific event information. Can be grasped.

Feature αq3. The specific notification means performs a notification start operation (press operation of the reset button 68c performed in a situation where the most recent base value is displayed on the first to fourth notification display devices 201 to 204). The gaming machine according to the characteristic αq1 or αq2, which starts notification of the specific event information based on the above.

According to the feature αq3, the notification start operation can be performed to start the notification of the specific event information when the specific event information needs to be confirmed. When the manager of the game hall notices that the predetermined ratio information is out of the theoretical value range of the predetermined ratio information, he/she can perform the notification start operation and confirm the specific event information. By making it possible to confirm the specific event information as necessary, it is possible to easily grasp the degree of convergence of the predetermined ratio information.

Feature αq4. The specific notification means starts notification of the specific event information based on the notification start operation being performed in a situation where the predetermined ratio information has been notified, and the gaming machine according to feature αq3. ..

According to the feature αq4, the correspondence relationship between the predetermined ratio information and the specific event information can be made easy to understand. Further, when the notified predetermined ratio information is out of the theoretical value range of the predetermined ratio information, the notification of the specific event information can be started and the degree of convergence of the predetermined ratio information can be grasped.

Feature αq5. Both the notification of the predetermined ratio information and the notification of the specific event information are configured to be performed by predetermined display means (first to fourth notification display devices 201 to 204).
The gaming machine according to feature αq4, wherein the notification of the predetermined ratio information is started after the notification of the specific event information is completed.

According to the feature αq5, since the notification of the predetermined ratio information and the notification of the specific event information are performed by the common predetermined display unit, the predetermined ratio information and the specific event information can be grasped by the predetermined display unit. be able to. This makes it easier to grasp the predetermined ratio information and the specific event information as compared with the configuration in which the display unit for notifying the predetermined ratio information and the display unit for notifying the specific event information are separated. can do. Therefore, it is possible to reduce the burden of monitoring the predetermined ratio information on the gaming hall monitor.

Since the notification of the predetermined ratio information is started after the notification of the specific event information is completed, the predetermined ratio information can be confirmed after grasping the information corresponding to the number of occurrences of the specific event. This makes it easy to grasp the degree of convergence of the predetermined ratio information.

Feature αq6. The predetermined notification means is a configuration for continuing the notification of the predetermined ratio information for a predetermined continuation period (display continuation time) when the notification of the predetermined ratio information is started,
When the notification of the specific event information is started in the situation where the predetermined ratio information is notified, the notification of the predetermined ratio information is continued over the predetermined continuation period after the notification of the specific event information is finished. The gaming machine described in the feature αq5, which is provided with means (a function of executing the processes of step SM504, step SM505, and step SM508 to step SM513 in the main CPU 63).

According to the characteristic αq6, since the notification of the predetermined ratio information is continued for the predetermined continuation period, the confirmation of the predetermined ratio information can be facilitated. In the configuration, regardless of the period during which the notification of the specific ratio information is performed before the notification of the specific event information is started, the notification of the specific ratio information is continued for a predetermined continuation period after the notification of the specific event information is completed. Is done. When the notification of the specific event information is started, the notification of the predetermined ratio information that has been performed until then is interrupted, and when the notification of the specific event information is completed, the notification of the predetermined ratio information is restarted, When the notification of the specific event information is started just before the notification period of the predetermined ratio information is ended, the notification period of the predetermined ratio information performed after the notification of the specific event information may be extremely short. On the other hand, since the notification period of the predetermined ratio information is newly started after the notification of the specific event information is completed, the notification period of the predetermined ratio information performed after the notification of the specific event information is changed to the predetermined continuation period. It can be secured over. Thereby, the notification of the predetermined ratio information performed after the notification of the specific event information can be made easy to understand.

Feature αq7. The predetermined ratio information when the specific event information becomes the reference information (shift reference number) is the history ratio information (base value stored in the first history area 312, base value stored in the second history area 313, and A sequential storage means (first history area 312, second history area 313, and third history area 314) for storing as a base value stored in the third history area 314;
The predetermined notification means is in a current status notification state in which the predetermined ratio information currently calculated by the second calculation means is notified (stored in the current area 311 in the first to fourth notification display devices 201 to 204). It is possible to control the predetermined display means (first to fourth notification display devices 201 to 204) so as to be in a state in which the base value is being notified) and is stored in the sequential storage means. The history notification state in which the history ratio information is notified (stored in any one of the first history area 312, the second history area 313, and the third history area 314 in the first to fourth notification display devices 201 to 204). The gaming machine according to any one of the features αq3 to αq6, characterized in that it is possible to control the predetermined display means so that the predetermined base value is notified.

According to the characteristic αq7, it is possible to confirm the predetermined ratio information currently calculated based on the notification given by the predetermined display means, and it is also possible to confirm the history ratio information sequentially stored in the storage means. Can be By making it possible to confirm the currently calculated predetermined ratio information, it is possible to grasp whether or not the currently calculated predetermined ratio information is within the theoretical value range of the predetermined ratio information, and the history ratio. By making it possible to confirm the information, it is possible to grasp whether or not the predetermined ratio information calculated in the past falls within the theoretical value range of the predetermined ratio information. By making it possible to confirm the predetermined ratio information calculated in the past, it is possible to check the time when the situation in which the predetermined ratio information is out of the theoretical value range of the predetermined ratio information can be traced back in the past. Further, it is possible to reduce the frequency of confirmation of the predetermined ratio information and reduce the monitoring load of the predetermined ratio information by the manager of the game hall.

Feature αq8. The predetermined ratio information calculated by the second calculating means is the total amount of the predetermined profit for the specific event information corresponding to the number of times the specific event occurs is less than a reference number (less than the initial reference number). In the case of the information corresponding to the ratio, the special notification means (a function for executing the processing of steps SM313 to SM315 in the main CPU 63 in the main CPU 63, which causes the special notification (initial calculation display) to be executed, and the step SM514 in the main CPU 63. ~ A function of executing the process of step SM517) is provided, The gaming machine according to any one of features αq1 to αq7.

According to the characteristic αq8, in the situation where the number of times the specific event has occurred is less than the reference number, the second calculation means calculates based on the fact that the special notification is given without confirming the specific event information. It can be understood that the degree of convergence of the predetermined ratio information is low. When the number of occurrences of the specific event is less than the reference number of times, the predetermined ratio information is highly likely to be out of the theoretical value range of the predetermined ratio information. By making it possible to easily understand that the number of occurrences of the specific event is less than the reference number of times, it is possible to reduce the frequency of occurrence of the situation in which the specific event information must be confirmed. As a result, it is possible to reduce the burden of monitoring the predetermined ratio information on the manager of the game hall.

Feature αq9. In the special notification means, the execution mode of the notification of the predetermined ratio information is a special mode (a mode in which blinking display of a character to be displayed on the first notification display device 201 and the second notification display device 202 is performed). The gaming machine according to the feature αq8, in which the special notification is executed by making the above.

According to the characteristic αq9, since the notification of the predetermined ratio information is performed in a special mode, the notification indicating that the number of times of occurrence of the specific event is less than the reference number of times is provided separately from the notification of the predetermined ratio information. It is possible to make it easier to understand the notification of the predetermined ratio information, as compared with the configuration of performing the above. In addition to the notification of the predetermined ratio information, the number of times a specific event has occurred is less than the reference number of times, without the need for a configuration for notifying that the number of times a particular event has occurred is less than the reference number of times. It is possible to grasp that there is a certain situation.

In addition, with respect to the configurations of the features αq1 to αq9, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the above characteristic αq group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, in a pachinko machine, the game machine front face section is provided with a dish storage section for storing the game balls given to the player, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, it is necessary to manage the gaming machine appropriately, and there is still room for improvement in this respect.

<Characteristic αr group>
Features αr1. A control unit (main CPU 63) for executing various processes and temporarily storing information in an internal storage unit (register of the main CPU 63) when the processes are executed,
The control means is
Predetermined process executing means (preferred test execution process, management execution process, and total division execution process of the main CPU 63 in the 93rd, 95th, and 96th embodiments) that executes a predetermined process (process corresponding to non-specific control) Function),
When the predetermined process is started by the predetermined process execution means, predetermined information (flag register information), which is at least part of the information stored in the internal storage means, is saved in the predetermined storage means (main RAM 65). Save execution means (function of executing processes of steps SL807 and SL821 in the main CPU 63, function of executing step SM806 of the main CPU 63),
Interruption prohibition means for prohibiting execution of interrupt processing (first timer interrupt processing, second timer interrupt processing) (function of executing the processing of steps SL807 and SL821 in the main CPU 63, executing the processing of step SM806 in the main CPU 63) Function),
Equipped with
A predetermined instruction (CALLI instruction in the 93rd, 95th and 96th embodiments) which is one instruction is set as an instruction for starting the predetermined processing in the program of the control means,
Execution of the predetermined instruction causes the save execution means to save the predetermined information in the predetermined storage means, prohibits execution of the interrupt processing by the interrupt prohibition means, and performs the predetermined processing by the predetermined process execution means. A gaming machine characterized by the start of.

According to the characteristic αr1, one predetermined command set in the program saves the predetermined information to the predetermined storage means by the save execution means, prohibits the execution of interrupt processing by the interrupt prohibition means, and performs the predetermined processing by the predetermined process execution means. Can be started. Therefore, it is possible to reduce the number of instructions set in the program for starting the predetermined process in a state where the predetermined information is saved and the interrupt process is prohibited from being executed, and the storage capacity for storing the program is reduced. Can be reduced.

Features αr2. The control means executes specific processing (processing corresponding to specific control), specific processing execution means (test firing test execution processing, management execution processing, and total division of the main CPU 63 in the 93rd, 95th, and 96th embodiments). Function that executes processing other than execution processing)
The predetermined storage means,
A specific storage area (a specific control work area 221 and a specific control stack area 222) in which information is stored when the specific processing is executed;
A predetermined storage area (a work area 223 for non-specific control, a stack area 224 for non-specific control) in which information is stored when the predetermined processing is executed;
Equipped with
The specific storage area can store and read information when the specific process is executed, and can read information but cannot store information when the predetermined process is executed. Yes,
The predetermined storage area can store and read information when the predetermined process is executed, and can read information but cannot store information when the specific process is executed. The gaming machine described in the feature αr1.

According to the feature αr2, the specific storage area can be treated as a dedicated storage area for the specific processing, and the predetermined storage area can be treated as a dedicated storage area for the predetermined processing.

Features αr3. The gaming machine according to feature αr2, wherein the specific process is executed when the interrupt process is started.

According to the characteristic αr3, the interrupt processing can be executed by using the specific storage area that has the configuration of the characteristic αr2 and can be treated as a dedicated storage area for the specific processing.

Features αr4. The gaming machine according to feature αr2 or αr3, wherein the predetermined command is executed in a situation where the specific process is being executed.

According to the characteristic αr4, by executing the predetermined instruction in the situation where the specific process is being executed, one instruction (predetermined instruction) causes the save execution means to save the predetermined information to the predetermined storage means and the interrupt prohibition means. The predetermined process can be started in a state where the execution of the interrupt process is prohibited. As a result, it is possible to simplify the processing configuration for saving the predetermined information in the predetermined storage means and prohibiting the execution of the interrupt processing to start the predetermined processing when the specific processing is being executed.

Features αr5. As the predetermined processing, a first predetermined processing (any one of the test shot test execution processing, the management execution processing, and the total division execution processing in the 93rd, 95th, and 96th embodiments) and the second predetermined processing (93th, Of the test shot test execution processing, the management execution processing, and the total division execution processing in the 95th and 96th embodiments, different processing from the first predetermined processing) is set.
As the predetermined instruction, a first predetermined instruction that is one instruction for starting the first predetermined processing (a CALLI instruction for executing any one of a test shot test execution processing, a management execution processing, and a total division execution processing). ) And a second predetermined command that is one command for starting the second predetermined process (to execute a process different from the first predetermined process among the test shot test execution process, the management execution process, and the total division execution process). CALLI command), and the gaming machine according to any one of the features αr1 to αr4.

According to the characteristic αr5, the first predetermined command causes the save execution means to save the predetermined information in the predetermined storage means, the interrupt prohibition means to prohibit the execution of the interrupt process, and the predetermined process execution means to start the first predetermined process. It can be carried out. Further, the second predetermined command can cause the save execution means to save the predetermined information in the predetermined storage means, the interrupt prohibition means to prohibit the execution of the interrupt process, and the predetermined process execution means to start the second predetermined process. .. Therefore, it is possible to save the predetermined information and reduce the number of instructions set in the program for starting the first predetermined process or the second predetermined process which is the predetermined process in a state where the execution of the interrupt process is prohibited. In addition, the storage capacity for storing the program can be reduced.

Features αr6. In the case of ending the predetermined process or after the end, the return execution unit for returning the predetermined information saved in the predetermined storage unit to the internal storage unit (function of executing the process of step SL916 in the main CPU 63, main side) A function of executing the processing of step SM116 in the CPU 63, a function of executing the processing of step SM916 in the main CPU 63, and a function of executing the processing of step SN609 in the main CPU 63). The gaming machine according to any one of 1.

According to the feature αr6, the configuration of the feature αr1 is provided, and when the predetermined process is executed by the predetermined command, the predetermined information is saved in the predetermined storage unit before the start of the predetermined process. With this configuration, the predetermined information saved in the predetermined storage unit is restored to the internal storage unit when or after the predetermined process is completed, so that after the predetermined process is performed and before the predetermined process is performed. It is possible to execute a process different from the predetermined process from the state of the internal storage means.

Features αr7. A specific instruction (a RETI instruction in the 93rd to 96th embodiments), which is one instruction, is set as an instruction for ending the predetermined processing in the program of the control means,
When the specific instruction is executed, the restoration execution means restores the predetermined information to the internal storage means, permits execution of the interrupt processing, and ends the predetermined processing. The gaming machine described in αr6.

According to the characteristic αr7, it is possible to restore the predetermined information to the internal storage means by the return executing means, permit execution of the interrupt processing, and terminate the predetermined processing by one specific instruction set in the program. Therefore, it is possible to reduce the number of instructions set in the program for returning the predetermined information to the internal storage means by the return executing means, permitting the execution of the interrupt processing, and ending the predetermined processing. The storage capacity for storing the program can be reduced.

Feature αr8. The gaming machine according to any one of features αr1 to αr7, wherein the predetermined information is information of a flag register provided in the internal storage means.

According to the characteristic αr8, by executing the predetermined instruction, it is possible to appropriately save the information in the flag register and start the predetermined processing.

Feature αr9. The control means is capable of executing repetitive processing (residual processing) that is repeatedly executed,
The gaming machine according to any one of features αr1 to αr8, wherein execution of the interrupt process is prohibited at the beginning of the repeating process, and the predetermined process is executed by the predetermined command at the end of the repeating process. ..

According to the characteristic αr9, by prohibiting the execution of the interrupt processing at the beginning of the repeated processing, it is possible to prevent the interrupt processing from being interrupted and executed during the execution of the repeated processing. Further, if the configuration is such that the predetermined process is executed by a predetermined command in the middle of the repetitive process, it becomes necessary to perform the process of prohibiting the activation of the interrupt process after the end of the predetermined process to execute the specific process. On the other hand, since the predetermined process is executed by the predetermined command at the end of the repeated process, the process of prohibiting the activation of the interrupt process after the execution of the predetermined process can be omitted. This can simplify the processing configuration of the repeated processing.

In addition, with respect to the configurations of the features αr1 to αr9, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αs group>
Features αs1. It is possible to execute a repeat process (residual process in the 93rd to 96th embodiments) that is repeatedly executed, and to execute an interrupt process (first timer interrupt process) based on the satisfaction of an interrupt condition. In a gaming machine equipped with means (main CPU 63),
The control means is
When a predetermined event (outgoing opening 24a, general winning opening 31, special electric winning device 32, first working opening 33, second working opening 34 entering a ball) occurs due to the execution of the game, the corresponding game History storage executing means (processing of SM204 in the main CPU 63) for storing history information in the history storage means (normal counter area 231) is executed (normal entrance management processing in the main CPU 63 is executed) Function),
Information derivation processing (processing of steps SN101 to SN104 in the main CPU 63) for deriving mode information (base value) corresponding to the result of the game using the history information stored in the history storage means. Information deriving means to be executed (function to execute the processing of steps SN101 to SN104 in the main CPU 63);
Equipped with
At least one of the history storage processing and the information derivation processing is executed in the repeating processing.

According to the characteristic αs1, when the predetermined event occurs, the history information corresponding to the predetermined event is stored in the history storage means. By storing the history information in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, using the history information stored in the history storage means, the mode information corresponding to the result of the game is derived. Therefore, by using the aspect information, it is possible to preferably manage the occurrence frequency of the predetermined event.

Since at least one of the history storage processing and the information derivation processing is configured to be executed in the iterative processing, the execution of the interrupt processing is performed in comparison with the configuration in which both the history storage processing and the information derivation processing are executed in the interrupt processing. The period can be shortened. As a result, it is possible to avoid the situation where the interrupt processing is not completed within the interrupt cycle.

Features αs2. It is possible to execute a repeat process (residual process in the 93rd to 96th embodiments) that is repeatedly executed, and to execute an interrupt process (first timer interrupt process) based on the satisfaction of an interrupt condition. In a gaming machine equipped with means (main CPU 63),
The control means is
When a predetermined event (outgoing opening 24a, general winning opening 31, special electric winning device 32, first working opening 33, second working opening 34 entering a ball) occurs due to the execution of the game, the corresponding game History storage executing means (processing of SM204 in the main CPU 63) for storing history information in the history storage means (normal counter area 231) is executed (normal entrance management processing in the main CPU 63 is executed) Function),
Information derivation processing (processing of steps SN101 to SN104 in the main CPU 63) for deriving mode information (base value) corresponding to the result of the game using the history information stored in the history storage means. Information deriving means to be executed (function to execute the processing of steps SN101 to SN104 in the main CPU 63);
Equipped with
One of the history storage processing and the information derivation processing is executed in the repeating processing, and the other of the history storage processing and the information derivation processing is executed in the interrupt processing.

According to the characteristic αs2, when a predetermined event occurs, history information corresponding to the predetermined event is stored in the history storage means. By storing the history information in the gaming machine itself, it is possible to prevent unauthorized access to the history information and unauthorized modification. Further, using the history information stored in the history storage means, the mode information corresponding to the result of the game is derived. Therefore, by using the aspect information, it is possible to preferably manage the occurrence frequency of the predetermined event.

Since one of the history storage process and the information derivation process is repeatedly executed, and the other of the history storage process and the information derivation process is executed in the interrupt process, both the history storage process and the information derivation process are performed. The execution period of the interrupt process can be shortened as compared with the configuration executed in the interrupt process. As a result, it is possible to avoid the situation where the interrupt processing is not completed within the interrupt cycle. Further, it becomes possible to periodically execute the process executed in the interrupt process of the history storage process and the information derivation process.

Features αs3. The gaming machine according to feature αs2, wherein the history storage process is executed in the interrupt process, and the information derivation process is executed in the repeating process.

According to the characteristic αs3, it is possible to increase the update frequency of the history information of the game stored in the history storage means by periodically executing the history storage processing for storing the history information of the game in the history storage means. Become. Further, by adopting a configuration in which the information derivation process is executed in the iterative process, the time required to execute the interrupt process can be shortened as compared with the configuration in which the information derivation process is executed in the interrupt process. As a result, it is possible to avoid the situation where the interrupt processing is not completed within the interrupt cycle.

Features αs4. The gaming machine according to feature αs3, wherein execution of the interrupt process is prohibited in a situation where the information derivation process is being performed.

According to the characteristic αs4, the configuration of the characteristic αs2 is provided, and in the information derivation process, the form information corresponding to the result of the game is derived using the history information stored in the history storage means. It is possible to prevent the history information stored in the history storage unit from being updated during the information derivation process by prohibiting the interrupt process from being interrupted and executed in the situation where the information derivation process is being performed. be able to. Further, it is possible to eliminate the process of saving the information used for the information derivation process at the start of the interrupt process and the process of restoring the information used for the information derivation process at the end of the interrupt process. As a result, the processing load on the control means can be reduced.

Features αs5. The control means is
Based on the history information, a reference trigger (the total number of game balls discharged from the game area PA in a situation that is neither the open/close execution mode depending on the jackpot result nor the high frequency support mode reaches the shift reference number) has occurred. A trigger specifying means (a function of the main CPU 63 for executing the processing of step SM316),
Based on the fact that the reference opportunity has been identified by the opportunity identifying means, the information deriving means uses the history information stored in the history storage means when the reference opportunity occurs. A storage executing unit (a function of executing the process of step SM302 in the main CPU 63) that executes a storage executing process (data shift process) for storing the derived form information in the form information storing unit (first history area 312). )When,
Equipped with
The gaming machine according to feature αs3 or αs4, wherein the storage execution process is executed in the interrupt process.

According to the characteristic αs5, the aspect information derived by the information deriving means using the history information stored in the history storage means is stored in the aspect information storage means when the reference trigger is generated. It is possible to grasp the mode information derived by the information deriving means by using the history information stored in the history storage means when the reference trigger occurs. Further, since the storage execution process is configured to be executed in the interrupt process, the period from when the trigger specifying unit identifies that the reference trigger has occurred until the storage execution process is executed becomes long. Can be prevented.

Features αs6. When the trigger specifying unit specifies that the reference trigger has occurred, the storage executing unit performs the interrupt processing at a processing time after the interrupt processing at which the specification is performed. The gaming machine according to feature αs5, which executes a memory execution process.

According to the feature αs6, the information derivation process is executed in the iterative process that is performed after the processing times of the interrupt process in which the reference trigger has been specified by the trigger specifying unit have been completed are The aspect information can be derived using the history information stored in the history storage means in the situation in which the reference trigger has occurred. Then, the storage execution process is executed in the process times of the interrupt process performed in the state in which the mode information is derived by the information derivation unit using the history information stored in the history storage unit in the situation where the reference trigger has occurred. Thus, when the reference trigger has occurred, the aspect information derived by the information deriving means can be stored in the aspect information storage means using the history information stored in the history storage means.

Features αs7. A game is played using a game medium (game ball).
This gaming machine is based on the occurrence of a profit-giving event (entering a game ball into the general winning opening 31, the special electricity winning device 32, the first working opening 33, and the second working opening 34) as the game is played. And a profit giving means (a function of executing the processes of steps S316 and S317 in the main CPU 63).
The history storage execution means is for causing the history storage means to execute storage of information corresponding to the profit given as the predetermined event.
The aspect information is used in a predetermined period (a period until the total number of game balls discharged from the game area PA in the situation where neither the open/close execution mode depending on the jackpot result nor the high frequency support mode reaches the shift reference number). The predetermined ratio information (base value) corresponding to the ratio of the total amount of the profits given in the predetermined period to the total number of the game media, according to any one of the features αs2 to αs6. Amusement machine.

According to the characteristic αs7, it is possible to grasp the information about the ratio of the total amount of the profits given in the predetermined period to the total number of the game media used in the predetermined period, based on the predetermined ratio information. As a result, the gaming machine can be managed appropriately.

Features αs8. The information deriving unit divides the total amount of the profits given in the predetermined period by the total number of the game media used in the predetermined period (the 93rd to 96th digits). In the embodiment, by adjusting the digit of the division result of the number of digits up to the fourth decimal place), the predetermined ratio information having a smaller number of digits than the predetermined number of digits is derived, and the game as described in the feature αs7. Machine.

According to the feature αs8, the division result of the predetermined digit number obtained by dividing the total amount of the profits given in the predetermined period by the total number of the game media used in the predetermined period is digit-adjusted and the predetermined ratio information is obtained. With the configuration for deriving, the accuracy of the derived predetermined ratio information can be improved. With the configuration of the characteristic αs2, one of the history storage process and the information derivation process is executed in the iterative process, and the other of the history storage process and the information derivation process is executed in the interrupt process. Since the history storage process and the information derivation process are distributed to the iterative process and the interrupt process, even if the time required for the information derivation process for adjusting the digit of the division result is long, the interrupt process does not fall within the interrupt cycle. You can avoid the situation that does not end with.

For the configurations of the features αs1 to αs8, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αt group>
Features αt1. A control unit (main CPU 63) for executing various processes and temporarily storing information in an internal storage unit (register of the main CPU 63) when the processes are executed,
The control means is
Of the various processes, other than a specific process execution unit that executes a specific process (a process corresponding to a specific control) (other than the test shot test execution process, management execution process, and total division execution process of the main CPU 63 in the 93rd to 96th embodiments) Function that executes the processing of
Predetermined process execution means for executing a predetermined process (process corresponding to non-specific control) of the various processes (test firing test execution process, management execution process and total division execution process of the main CPU 63 in the 93rd to 96th embodiments) Function to execute)
A predetermined value that is at least a part of the information stored in the internal storage means when the predetermined process is executed from the state in which the specific process is executed or when the predetermined process is executed. A function for executing the processing of steps SL807 and SL821 of the main CPU 63 in the 93rd, 95th and 96th embodiments for saving information (information in the flag register) to a predetermined storage means (main RAM 65). A function of executing the process of step SM806 in the main CPU 63, a function of executing the process of step SN219 of the main CPU 63 in the 94th embodiment),
In the case of ending the predetermined process, or after the end, the return execution unit for returning the predetermined information saved in the predetermined storage unit to the internal storage unit (main CPU 63 in the 93rd, 95th and 96th embodiments) Function for executing the processing of steps SL807 and SL821, the function of executing the processing of step SM806 in the main CPU 63, the function of executing the processing of step SN223 of the main CPU 63 in the 94th embodiment).
Equipped with
As the predetermined process, a first predetermined process (any one of the test shot test execution process, the management execution process, and the total division execution process in the 93rd to 96th embodiments) and the second predetermined process (93th to 96th embodiments) Of the trial shot test execution process, the management execution process, and the total division execution process in the embodiment) different from the first predetermined process) are set.
When the first predetermined process is executed or when the first predetermined process is executed, the save execution means saves the predetermined information in a predetermined storage means to save the first predetermined process. When ending or after ending, the predetermined information saved in the predetermined storage means is returned to the internal storage means by the return execution means,
When the second predetermined process is executed or when the second predetermined process is executed, the save execution unit saves the predetermined information in a predetermined storage unit to save the second predetermined process. A game machine characterized in that, when or after the end, the predetermined information saved in the predetermined storage means is returned to the internal storage means by the return execution means.

According to the characteristic αt1, the predetermined information is saved in the predetermined storage means when the first predetermined process is executed or the first predetermined process is executed from the condition in which the specific process is executed. It Accordingly, when the first predetermined process is executed, it is possible to prevent the information stored in the internal storage means from being rewritten when the specific process is executed. Further, when or after the first predetermined process is ended, the predetermined information saved in the predetermined storage means is restored to the internal storage means. As a result, when the first predetermined process is completed, it is possible to execute a process different from the first predetermined process from the state of the internal storage means before the execution of the first predetermined process.

The predetermined information is saved in the predetermined storage means when the second predetermined process is executed or the second predetermined process is executed from the condition where the specific process is being executed. Accordingly, when the second predetermined process is executed, it is possible to prevent the information stored in the internal storage unit from being rewritten when the specific process is executed. Further, when or after the second predetermined process is ended, the predetermined information saved in the predetermined storage means is restored to the internal storage means. As a result, when the second predetermined process is completed, it is possible to execute a process different from the second predetermined process from the state of the internal storage means before the execution of the second predetermined process.

The first predetermined process and the second predetermined process exist as the predetermined process, and the first predetermined process and the second predetermined process are configured to be executed discontinuously. Compared with the configuration in which the first predetermined process and the second predetermined process are continuously executed without returning the information to the internal storage means, the state in which the predetermined process is executed is prevented from continuing for a long time. can do. As described above, various controls can be suitably performed.

Features αt2. The predetermined storage means,
A specific storage area (a specific control work area 221 and a specific control stack area 222) in which information is stored when the specific processing is executed;
A predetermined storage area (a work area 223 for non-specific control, a stack area 224 for non-specific control) in which information is stored when the predetermined processing is executed;
Equipped with
The specific storage area can store and read information when the specific process is executed, and can read information but cannot store information when the predetermined process is executed. Yes,
The predetermined storage area can store and read information when the predetermined process is executed, and can read information when the specific process is executed but cannot store information. The gaming machine described in the feature αt1 characterized in that there is.

According to the feature αt2, it is possible to handle the specific storage area as a dedicated storage area for the specific processing, and it is possible to handle the predetermined storage area as a dedicated storage area for the predetermined processing. When the predetermined predetermined information is saved in the predetermined storage unit, the first predetermined process is executed and the first predetermined process is executed and the first predetermined process is finished or after the first predetermined process is finished. The predetermined information saved in the storage means can be restored in the internal storage means. When the second predetermined process is executed by using the predetermined storage area in a state where the predetermined information is saved in the predetermined storage unit by the configuration of the above characteristic αt1, and the second predetermined process is ended or after the end. The predetermined information saved in the predetermined storage means can be restored in the internal storage means.

Features αt3. The control means is capable of executing repeated processing (residual processing in the 93rd to 96th embodiments) that is repeatedly executed, and performs interrupt processing (first timer interrupt processing) based on the satisfaction of an interrupt condition. Is feasible,
The gaming machine according to feature αt1 or αt2, wherein the first predetermined process is executed in the repetitive process and the second predetermined process is executed in the interrupt process.

According to the characteristic αt3, the second predetermined process is executed in the interrupt process, so that the second predetermined process can be executed regularly. Moreover, since the first predetermined process is executed in the repetitive process, the first predetermined process can be repeatedly executed in a period in which the interrupt process is not executed. Since the first predetermined process and the second predetermined process, which are the predetermined processes, are distributed to the repeated process and the interrupt process, the period in which the predetermined process is continuously performed can be shortened. Further, the execution period of the interrupt process can be shortened as compared with the configuration in which both the first predetermined process and the second predetermined process are executed in the interrupt process. As a result, it is possible to avoid a situation in which the interrupt processing does not end within the interrupt cycle.

Features αt4. The control means is capable of executing repeated processing (residual processing in the 93rd to 96th embodiments) that is repeatedly executed, and performs interrupt processing (first timer interrupt processing) based on the satisfaction of an interrupt condition. Is feasible,
The gaming machine according to the feature αt1 or αt2, wherein the first predetermined process and the second predetermined process are both executed by one of the repeating process and the interrupt process.

According to the characteristic αt4, since the first predetermined process and the second predetermined process, which are the predetermined processes, are configured to be executed by one of the repeat process and the interrupt process, the first process among the repeat process and the interrupt process is performed. The execution period of the process on the side where the predetermined process and the second predetermined process are not executed can be shortened. As a result, it is possible to prevent the execution period of the repeating process or the interrupt process from being extended and delaying the execution timing of the interrupt process.

Features αt5. The first predetermined process and the second predetermined process are both processes executed to derive a predetermined parameter corresponding to a game result, according to any one of features αt1 to αt4. Game machine.

According to the characteristic αt5, a process for deriving a predetermined parameter corresponding to the result of the game is executed in the first predetermined process and the second predetermined process which are the predetermined processes. When the first predetermined process is executed or the first predetermined process is executed, the predetermined information is saved in the predetermined storage unit and the first predetermined process is completed. In the case of doing or after finishing, the saved predetermined information is restored to the internal storage means. Further, when the second predetermined process is executed or when the second predetermined process is executed, the predetermined information is saved in the predetermined storage unit, and the second predetermined process is ended or after the second predetermined process is ended. The saved predetermined information is restored to the internal storage means. Therefore, it is possible to execute the process of deriving the predetermined parameter corresponding to the result of the game while preventing the information stored in the internal storage means from being rewritten when the specific process is executed. Further, when the process of deriving a predetermined parameter corresponding to the result of the game is completed, it is possible to execute a process different from the process from the state of the internal storage means before the execution of the process.

The first predetermined process and the second predetermined process, which are the predetermined processes, are discontinuously executed by the configuration of the characteristic αt1 described above, so that the first predetermined process and the second predetermined process are continuously executed. As compared with the configuration described above, it is possible to prevent the state in which the process of deriving a predetermined parameter corresponding to the result of the game is being executed as the predetermined process from continuing for a long time.

Features αt6. A game is played using a game medium (game ball).
This gaming machine is based on the occurrence of a profit-giving event (entering a game ball into the general winning opening 31, the special electricity winning device 32, the first working opening 33, and the second working opening 34) as the game is played. And a profit giving means (a function of executing the processes of steps S316 and S317 in the main CPU 63).
Both of the first predetermined process and the second predetermined process are based on the total number of game balls discharged from the game area PA in a predetermined period (a situation in which neither the open/close execution mode according to the big hit result nor the high frequency support mode is used as the shift criterion. (Period until reaching the number) A process executed to derive predetermined ratio information corresponding to the ratio of the total amount of the profit given in the predetermined period to the total number of the game media used. The gaming machine according to any one of the features αt1 to αt5.

According to the characteristic αt6, it is possible to grasp the information about the ratio of the total amount of profits given in the predetermined period to the total number of game media used in the predetermined period, based on the predetermined ratio information. As a result, the gaming machine can be managed appropriately.

Features αt7. A predetermined instruction (CALLI instruction in the 93rd, 95th and 96th embodiments) which is one instruction is set as an instruction for starting the predetermined processing in the program of the control means,
Execution of the predetermined instruction causes the save execution means to save the predetermined information in the predetermined storage means, prohibit execution of interrupt processing, and start the predetermined processing by the predetermined process execution means. And
As the predetermined instruction, a first predetermined instruction that is one instruction for starting the first predetermined processing (a CALLI instruction for executing any one of a test shot test execution processing, a management execution processing, and a total division execution processing). ) And a second predetermined command that is one command for starting the second predetermined process (to execute a process different from the first predetermined process among the test shot test execution process, the management execution process, and the total division execution process). CALLI command), and the gaming machine according to any one of features αt1 to αt6.

According to the characteristic αt7, the one predetermined instruction set in the program saves the predetermined information to the predetermined storage means by the save execution means, prohibits the execution of the interrupt processing by the interrupt prohibition means, and the predetermined processing by the predetermined process execution means. Can be started. Therefore, it is possible to reduce the number of instructions set in the program for starting the predetermined process in a state where the predetermined information is saved and the interrupt process is prohibited from being executed, and the storage capacity for storing the program is reduced. Can be reduced.

Since the first predetermined process is started by the first predetermined command, the first predetermined process can be started in a state where the predetermined information is saved and the execution of the interrupt process is prohibited. Further, it is possible to reduce the number of instructions set in the program for starting the first predetermined process in a state in which the predetermined information is saved and the execution of the interrupt process is prohibited, and a memory for storing the program. The capacity can be reduced.

Since the second predetermined process is started by the second predetermined command, the second predetermined process can be started in a state where the predetermined information is saved and the execution of the interrupt process is prohibited. Further, it is possible to reduce the number of instructions set in the program for starting the second predetermined process in a state in which the predetermined information is saved and the execution of the interrupt process is prohibited, and a memory for storing the program. The capacity can be reduced.

Feature αt8. The gaming machine according to any one of features αt1 to αt7, wherein the predetermined information is information of a flag register provided in the internal storage means.

According to the characteristic αt8, the information in the flag register is saved in the predetermined storage unit when the first predetermined process is executed or the first predetermined process is executed, and the first predetermined process is ended. In the case of performing or after the end, the information of the flag register saved in the predetermined storage means can be restored to the internal storage means. When the second predetermined process is to be executed or when the second predetermined process is to be executed, the flag register information is saved in the predetermined storage unit, and the second predetermined process is ended or ended. After that, the information in the flag register saved in the predetermined storage means can be restored in the internal storage means.

In addition, with respect to the configurations of the features αt1 to αt8, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αu group>
Features αu1. A control unit (main CPU 63) for executing various processes and temporarily storing information in an internal storage unit (register of the main CPU 63) when the processes are executed,
The control means is
Specific processing execution means (processing corresponding to specific control) of the various types of processing (test firing test execution processing, management execution processing and total division execution processing by the main CPU 63 in the 94th and 95th embodiments) Function that executes processing other than),
Predetermined process execution means for executing a predetermined process (process corresponding to non-specific control) among the various processes (test firing test execution process, management execution process, and total division execution in the main CPU 63 in the 94th and 95th embodiments) Function to execute processing),
A predetermined value that is at least a part of the information stored in the internal storage means when the predetermined process is executed from the state in which the specific process is executed or when the predetermined process is executed. Evacuation executing means for saving information (flag register information) to a predetermined storage means (main RAM 65) (function for executing the process of step SN219 of the main CPU 63 in the 94th embodiment, main in the 95th embodiment) A function of executing the processing of steps SL807 and SL821 of the CPU 63, a function of executing the processing of step SM806 in the main CPU 63),
In the case of ending the predetermined process or after the predetermined process, a return execution unit for returning the predetermined information saved in the predetermined storage unit to the internal storage unit (the process of step SN223 of the main CPU 63 in the 94th embodiment A function to execute, a function to execute the processes of steps SL807 and SL821 of the main CPU 63 in the 95th embodiment, and a function to execute the process of step SM806 in the main CPU 63).
Equipped with
As the predetermined processing, the first predetermined correspondence processing (one of the test shot test execution processing and the management execution processing in the 94th and 95th embodiments) and the second predetermined correspondence processing (94th and 95th) are performed so that the control targets are different. The other of the test firing test execution process and the management execution process in the embodiment is set,
When the situation becomes such that the first predetermined correspondence process is executed or the situation where the first predetermined correspondence process is executed, the save execution means saves the predetermined information in the predetermined storage means, and thereafter, When the first predetermined correspondence process and the second predetermined correspondence process are executed and the second predetermined correspondence process is ended or after the end, the predetermined information saved in the predetermined storage means is stored in the internal by the restoration execution means. A game machine characterized by being configured to be restored to a storage means.

According to the feature αu1, it is possible to execute the first predetermined correspondence process and the second predetermined correspondence process which are the predetermined processes in a state where the predetermined information is saved in the predetermined storage means. With this, when the first predetermined process and the second predetermined process are executed, it is possible to prevent the information stored in the internal storage unit from being rewritten when the specific process is executed. Further, the predetermined information saved in the predetermined storage means is restored to the internal storage means when or after the first predetermined correspondence processing and the second predetermined correspondence processing are ended. As a result, when the first predetermined correspondence process and the second predetermined correspondence process are completed, the state of the internal storage means before the execution of the first predetermined correspondence process and the second predetermined correspondence process is changed to the first predetermined correspondence process and the second predetermined correspondence process. It is possible to execute a process different from the predetermined handling process.

After the first predetermined correspondence process is executed while the predetermined information is saved in the predetermined storage means, the second predetermined correspondence process is executed without returning the predetermined information to the internal storage means. This makes it possible to omit the process of returning the predetermined information to the internal storage means at the end of the first predetermined correspondence process and the process of saving the predetermined information to the predetermined storage means at the start of the second predetermined correspondence process. With this, it is possible to simplify the processing configuration for executing the first predetermined correspondence processing and the second predetermined correspondence processing, which are the predetermined processing in a state where the predetermined information is saved in the predetermined storage unit.

Features αu2. The predetermined storage means,
A specific storage area (a specific control work area 221 and a specific control stack area 222) in which information is stored when the specific processing is executed;
A predetermined storage area (a work area 223 for non-specific control, a stack area 224 for non-specific control) in which information is stored when the predetermined processing is executed;
Equipped with
The specific storage area can store and read information when the specific process is executed, and can read information but cannot store information when the predetermined process is executed. Yes,
The predetermined storage area can store and read information when the predetermined process is executed, and can read information when the specific process is executed but cannot store information. The gaming machine described in the feature αu1, which is characterized by being present.

According to the characteristic αu2, it is possible to handle the specific storage area as a storage area dedicated to the specific processing, and it is possible to handle the predetermined storage area as a dedicated storage area for the predetermined processing.

Features αu3. The gaming machine according to feature αu1 or αu2, wherein the predetermined information is information of a flag register provided in the internal storage means.

According to the characteristic αu3, when the situation becomes such that the first predetermined correspondence processing is executed or the situation where the first predetermined correspondence processing is executed, the information in the flag register is saved in the predetermined storage means and the second predetermined correspondence processing is performed. When or after the processing is finished, the information in the flag register saved in the predetermined storage means can be restored in the internal storage means.

Features αu4. As the predetermined process, a third predetermined corresponding process (total division execution process) is set,
When the situation becomes such that the third predetermined correspondence processing is executed or the situation where the third predetermined correspondence processing is executed, the save execution means saves the predetermined information in a predetermined storage means, and the third predetermined correspondence processing is performed. Any of the characteristics αu1 to αu3 characterized in that the predetermined information saved in the predetermined storage means is returned to the internal storage means by the return execution means when or after the corresponding processing is ended. The gaming machine described in 1.

According to the characteristic αu4, it is possible to execute the third predetermined corresponding process which is the predetermined process in a state where the predetermined information is saved in the predetermined storage means. Accordingly, when the third predetermined process is executed, it is possible to prevent the information stored in the internal storage means from being rewritten when the specific process is executed. Further, when or after the third predetermined correspondence process is ended, the predetermined information saved in the predetermined storage means is restored to the internal storage means. As a result, when the third predetermined correspondence process is completed, it is possible to execute a process different from the third predetermined correspondence process from the state of the internal storage means before the execution of the third predetermined correspondence process.

Features αu5. The gaming machine according to feature αu4, wherein both the second predetermined correspondence process and the third predetermined correspondence process are processes executed to derive a predetermined parameter corresponding to the result of the game.

According to the characteristic αu5, processing for deriving a predetermined parameter corresponding to the result of the game is executed in the second predetermined processing and the third predetermined processing which are the predetermined processing. With the configuration of the characteristic αu1, the first predetermined correspondence processing and the second predetermined correspondence processing are executed while the predetermined information is saved in the predetermined storage means, and the first predetermined correspondence processing and the second predetermined correspondence processing are executed. When or after the end, the predetermined information saved in the predetermined storage means is restored to the internal storage means. In addition, the third predetermined correspondence process is executed in a state in which the predetermined information is saved in the predetermined storage means, and the predetermined storage is performed after or after the third predetermined correspondence process is completed. The predetermined information saved in the means is restored in the internal storage means. As described above, since the second predetermined process and the third predetermined process, which are the predetermined processes, are configured to be discontinuously executed, the second predetermined process and the third predetermined process are compared to the configuration that is continuously executed. Then, it is possible to prevent the state in which the process for deriving the predetermined parameter corresponding to the result of the game is being executed as the predetermined process from continuing for a long time.

Features αu6. A game is played using a game medium (game ball).
This gaming machine is based on the occurrence of a profit-giving event (entering a game ball into the general winning opening 31, the special electricity winning device 32, the first working opening 33, and the second working opening 34) as the game is played. And a profit giving means (a function of executing the processes of steps S316 and S317 in the main CPU 63).
Both of the second predetermined correspondence processing and the third predetermined correspondence processing, the total number of gaming balls discharged from the game area PA in a predetermined period Executed to derive predetermined ratio information (base value) corresponding to the ratio of the total amount of the profits given in the predetermined period to the total number of the game media used in the period until reaching the shift reference number) The game machine according to the feature αu4 or αu5, which is characterized in that the process is performed.

According to the characteristic αu6, it is possible to grasp the information about the ratio of the total amount of profits given in the predetermined period to the total number of the game media used in the predetermined period based on the predetermined percentage information. As a result, the gaming machine can be managed appropriately. Further, the second predetermined processing and the third predetermined processing, which are the processing executed to derive the predetermined ratio information, are discontinuously executed, so that the second predetermined processing and the third predetermined processing are performed. It is possible to prevent the state in which the process executed for deriving the predetermined ratio information is being executed from continuing for a long time, as compared with the configuration in which is executed continuously.

Features αu7. The second predetermined correspondence process is a process for measuring the total number of the game media used in the predetermined period and the total amount of the profit given in the predetermined period (step SM304 and step SM306 in the main CPU 63). Processing),
The third predetermined correspondence process is a process of calculating the predetermined ratio information based on dividing the total amount of the profit given in the predetermined period by the total number of the game media used in the predetermined period (main). The processing of step SN101 to step SN104 in the side CPU 63)), the gaming machine described in the characteristic αu6.

According to the characteristic αu7, the process for measuring the total number of game media used in the predetermined period and the total amount of the profit given in the predetermined period, and the total amount of the profit given in the predetermined period in the predetermined period The process of calculating the predetermined ratio information based on division by the total number of used game media can be executed discontinuously. Therefore, as compared with a configuration in which these processes are continuously executed, it is possible to prevent the state in which the process for deriving the predetermined parameter is being executed from continuing for a long time.

Features αu8. The control means is capable of executing repetitive processing (residual processing in the 94th and 95th embodiments) that is repeatedly executed, and executes interrupt processing (first interrupt processing) based on satisfaction of an interrupt condition. Is possible,
One of the second predetermined correspondence process and the third predetermined correspondence process is executed by the repeating process, and the other of the second predetermined correspondence process and the third predetermined correspondence process is executed by the interrupt process. The gaming machine according to any one of the features αu4 to αu7.

According to the feature αu8, one of the second predetermined correspondence processing and the third predetermined correspondence processing is executed in the iterative processing, and the other of the second predetermined correspondence processing and the third predetermined correspondence processing is executed in the interrupt processing. As a result, the execution period of the iterative process can be shortened as compared with the configuration in which both the second predetermined corresponding process and the third predetermined corresponding process are executed in the repetitive process. Further, the execution period of the interrupt process can be shortened as compared with the configuration in which both the second predetermined corresponding process and the third predetermined corresponding process are executed in the interrupt process. As a result, it is possible to prevent the execution timing of the interrupt processing from being delayed. Further, it becomes possible to periodically execute the process executed in the interrupt process of the second predetermined correspondence process and the third predetermined correspondence process.

In addition, with respect to the configurations of the features αu1 to αu8, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the inventions related to the characteristic αr group, the characteristic αs group, the characteristic αt group, and the characteristic αu group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, in a pachinko machine, the game machine front face section is provided with a dish storage section for storing the game balls given to the player, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as exemplified above, various controls need to be suitably performed, and there is still room for improvement in this respect.

<Characteristic αv group>
Features αv1. A function for executing supply start processing (step SN801 to step SN821) for executing supply start processing (step SN801 to step SN821) when the supply of operating power is started (main CPU 63 in the 97th embodiment, step SN801 to step SN821). ),
In a gaming machine in which the type of processing executed in the supply start corresponding processing differs depending on the supply start situation when the supply of operating power is started,
Specific result storage processing (main side in the 97th embodiment, which specifies the content of the supply start situation when the supply of the operating power is started and stores the specified result in the determination storage area (judgment register 651) The CPU 63 includes a step SN802, a step SN803, and a step SN805 for executing a specific result storage execution unit (a function for executing the steps SN802, SN803, and SN805 of the main CPU 63 in the 97th embodiment).
The supply start support means executes a process of a type corresponding to the information stored in the determination storage area as the supply start support process after the specific result storage process is executed. Machine.

According to the feature αv1, the content of the supply start situation when the supply of the operating power is started is specified, and the specified result is stored in the determination storage area. Then, after the specific result storing process is executed, a type of process corresponding to the information stored in the determination storage area is executed as the supply start supporting process. As a result, it is possible to collectively specify the supply start situation when the supply of the operating power is started, and then execute the optimum type of processing for the collectively specified result as the supply start correspondence processing. Become. Therefore, it is possible to preferably execute the supply start handling process when the supply of the operating power is started.

Feature αv2. The determination storage area is composed of a plurality of bits (7th to 0th bits B7 to B0),
The specific result storage executing means corresponds to a supply start situation of a type that has not occurred, with the bit corresponding to the supply start situation of the type that has occurred being one of two values of "0" and "1". The gaming machine according to feature αv1, wherein the specific result storing process is executed so that the bit to be set is the other of the two values of “0” and “1”.

According to the characteristic αv2, the determination storage area is composed of a plurality of bits, and in the identification result storage processing, the bit corresponding to the content of the identified supply start situation is one of the binary values “0” and “1”. You only have to choose one. Therefore, the processing load of the specific result storing process can be reduced.

Features αv3. The supply start responding means executes means of processing of a type corresponding to a numerical value specified by the plurality of bits as the supply start responding processing (processing of steps SN806 and SN817 of the main CPU 63 in the 97th embodiment). The game machine according to the feature αv2.

According to the feature αv3, the type of processing corresponding to the numerical value specified from the plurality of bits in the determination storage area can be executed as the supply start corresponding processing. This makes it possible to specify the type of processing to be executed as the supply start handling processing without individually specifying the numerical values stored in the plurality of bits of the determination storage area.

Features αv4. The supply start coping means executes a predetermined type of processing as the supply start coping processing when “1” is stored in a predetermined bit of the plurality of bits (main side in the 97th embodiment). The gaming machine according to feature αv3, which is provided with a function of executing the processing of step SN811, step SN813, and step SN814 of the CPU 63).

According to the characteristic αv4, as a method of specifying the type of processing to be executed as the supply start corresponding processing, there is a case of specifying the type of processing to be executed based on a numerical value specified from a plurality of bits of the determination storage area. In some cases, the type of processing to be executed may be specified based on whether or not “1” is stored in a predetermined bit of the determination storage area. As a result, it is possible to preferably identify the type of processing to be executed as the supply start corresponding processing.

Features αv5. The determination storage area includes a plurality of unit areas (setting key flag (7th bit B7), reset button flag (6th bit B6), abnormality flag (5th bit B5), setting change power failure flag (4th bit B4). ), setting confirmation power failure flag (3rd bit B3)),
The specific result storage executing means,
It is specified whether or not it is the first situation (the situation where the setting key insertion portion 68a is turned on or the data abnormality of the main RAM 63 occurs), and the first situation is confirmed. When specified, the first status information (information of “1”) is stored in the first area (setting key flag (7th bit B7) or abnormality flag (5th bit B5)) of the plurality of unit areas in the determination storage area. ) Is stored (a function of executing the process of step SP202 of the main CPU 63 in the 97th embodiment or a function of executing the process of step SN905 of the main CPU 63 in the 97th embodiment),
It is determined whether or not the second situation (the situation in which the reset button 68c is pressed) is specified, and when the second situation is specified, the plurality of unit areas in the determination storage area are specified. Of the second area (reset button flag (sixth bit B6)), means for storing the second status information (information of "1") (the processing of step SP204 of the main CPU 63 in the 97th embodiment) is executed. Function),
The gaming machine according to any one of the features αv1 to αv4.

According to the characteristic αv5, when the supply start situation when the supply of the operating power is started is the first situation, the first situation information corresponding thereto is stored in the first area of the determination storage area, When the supply start situation is the second situation when the supply of the operating power is started, the second situation information corresponding thereto is stored in the second area of the determination storage area. As a result, the information corresponding to the supply start status can be individually stored in the determination storage area.

Features αv6. The supply start responding means,
Means for executing a first corresponding process when the first situation information is stored in the first area and the second situation information is stored in the second area (main CPU 63 in the 97th embodiment) Step SN807 to step SN810)),
Means for executing a second handling process when the first situation information is not stored in the first area and the second situation information is stored in the second area (main side in the 97th embodiment) A function of executing the processing of step SN815 of the CPU 63),
The gaming machine described in the feature αv5.

According to the characteristic αv6, the first situation information is stored in the first area under both the condition for executing the first corresponding process and the condition for executing the second corresponding process as the supply start corresponding process. Includes the condition of being present. In this case, after the information is stored in the determination storage area in the specific result storage processing, the type of processing corresponding to the information stored in the determination storage area is executed as the supply start processing. Then, in the case of specifying whether or not to execute one of the first and second corresponding processes and then specifying whether or not to execute the other, whether or not the first situation occurs at each specific timing Need not be specified, and only the determination storage area needs to be confirmed.

Features αv7. The supply start responding means,
Means for executing a first corresponding process when the first situation information is stored in the first area (a function for executing the process of step SN812 of the main CPU 63 in the 97th embodiment);
Means for executing a second corresponding process when the second situation information is stored in the second area (a function for executing the process of step SN815 of the main CPU 63 in the 97th embodiment);
Equipped with
The gaming machine according to feature αv5, wherein when both the first situation information and the second situation information are stored, execution of the first corresponding process is prioritized.

According to the feature αv7, when the first situation information is stored in the determination storage area, the first handling process is executed, and when the second situation information is stored in the determination storage area, the first response information is stored. In the configuration in which the two-correspondence process is executed, when both the first situation information and the second situation information are stored, the execution of the first-correspondence process is prioritized. Accordingly, even in the configuration in which the information corresponding to the supply start situation is collectively stored in the determination storage area, it is possible to execute the process according to the predetermined priority as the supply start correspondence process.

Feature αv8. When both the first situation information and the second situation information are stored, the first handling process is executed, and the second handling process is not executed in the current supply start handling process this time. The gaming machine described in the feature αv7.

According to the feature αv8, when the execution of the first handling process is prioritized, the second handling process is not performed even if the second situation information is stored in the determination storage area. This makes it possible to reduce the processing load of the supply start handling processing.

Feature αv9. In the plurality of unit areas,
A unit area (setting key flag (7th bit B7), reset button flag (6th bit B6)) in which information corresponding to the presence or absence of an operation on a predetermined operation means is stored,
A unit area (abnormality flag (fifth bit B5)) in which information corresponding to the presence or absence of occurrence of a predetermined abnormality is stored,
The gaming machine according to any one of the features αv5 to αv8.

According to the feature αv9, it is possible to specify the presence/absence of the operation on the predetermined operation means by using the determination storage area, and it is possible to specify the presence/absence of the occurrence of the predetermined abnormality.

Feature αv10. In the plurality of unit areas, a unit area (setting changing power interruption flag (4th bit B4)) in which information corresponding to whether or not the specific process was executed when the supply of the operating power was stopped last time is stored. The gaming machine according to any one of the features αv5 to αv9, which includes a setting confirmation power interruption flag (third bit B3)).

According to the feature αv10, it is possible to use the determination storage area to identify whether or not the identification process was executed at the previous stop of the supply of operating power.

In addition, with respect to the configurations of the features αv1 to αv10, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, and features βA1 to βA. 4. Any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the characteristic αv group, it is possible to solve the following problems.

Pachinko machines and slot machines are known as game machines. For example, in a pachinko machine, the game machine front face section is provided with a dish storage section for storing the game balls given to the player, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, the process at the time of starting the supply of the operating power needs to be suitably executed, and there is still room for improvement in this respect.

<Characteristic αw group>
Features αw1. A control unit (main CPU 63) that executes various processes and temporarily stores information in the information storage unit (main RAM 65) when the processes are executed,
The control means is
First erasing means for erasing predetermined information stored in the information storage means based on occurrence of an erasure trigger (RAM clear operation) when supply of operating power is started (Implementation of 97th embodiment) Function of executing the process of step SN815 of the main CPU 63 in the embodiment),
Even if the erasure trigger does not occur when the supply of the operating power is started, it is stored in a predetermined storage area (checksum storage area 653) which is a partial storage area of the information storage means. Second erasing means for erasing information (function of executing the process of step SN804 of the main CPU 63 in the 97th embodiment);
A gaming machine characterized by being equipped with.

According to the characteristic αw1, not only the information stored in the information storage unit is erased when the erasing trigger is generated when the supply of the operating power is started, but also the supply of the operating power is started. In some cases, the information stored in the predetermined storage area, which is a partial storage area of the information storage means, is erased even if the erasure trigger has not occurred. As a result, when the supply of the operating power is started, even if the erasure trigger is not generated, it is possible to set the state in which the information is not stored in the predetermined storage area.

Features αw2. The control means is
Power failure calculation means for calculating the total value of information about all storage areas of the information storage means when the supply of operating power is stopped (the processing of step SN921 of the main CPU 63 in the 97th embodiment is executed). Function),
Predetermined storage execution means for storing information corresponding to the numerical value of the result of executing predetermined arithmetic processing (step SN922) on the total value calculated by the power failure calculation means in the predetermined storage area of the information storage means (first Function of executing the processes of steps SN922 and SN923 of the main CPU 63 in the 97th embodiment),
By using the information stored in the predetermined storage area when the supply of the operating power is started, the information stored in the information storage means is the information at the time of the previous stop of the supply of the operating power to the control means. Means for executing a change specifying process for specifying whether or not the change has occurred (a function for executing the processes of steps SN901 and SN902 of the main CPU 63 in the 97th embodiment),
Equipped with
The gaming machine according to feature αw1, wherein the second erasing means erases the information stored in the predetermined storage area after the change identifying process is executed.

According to the characteristic αw2, when the supply of the operating power is stopped, the total value of the information about all the storage areas of the information storage unit is calculated, and the predetermined arithmetic processing is executed on the calculated total value. Information corresponding to the numerical value of the result is stored in a predetermined storage area of the information storage means. When the supply of the operating power is started, the information stored in the predetermined storage area is used to change the information stored in the information storage means from the information when the supply of the operating power was stopped last time. The change identifying process for identifying whether or not the change is present is executed. This makes it possible to specify whether or not the information in the information storage means is normal when the supply of operating power is started. In this case, when the supply of the operating power is started, the information stored in the predetermined storage area is erased after the change identifying process is executed. Thus, even if the supply of the operating power is stopped at an arbitrary timing, it is possible to ensure that no information is stored in the predetermined storage area at the timing when the supply of the operating power is stopped. It will be possible.

Feature αw3. The predetermined calculation process is a process of calculating a two's complement of the total value calculated by the power failure calculation means,
The predetermined storage executing means stores the two's complement in the predetermined storage area,
The change identifying process calculates a total value of information about all storage areas of the information storage unit, and determines whether or not the calculated total value is “0”. The game machine described.

According to the characteristic αw3, when the supply of the operating power is stopped, the two's complement to the total value of the information about all the storage areas of the information storage unit is stored in the predetermined storage area and the supply of the operating power is performed. When started, the total value of information about all the storage areas of the information storage means is calculated. In this case, the information stored in the predetermined storage area is erased after the change identifying process is executed when the supply of the operating power is started with the configuration of the characteristic αw2, so that the operating power is supplied. When is stopped, the information in the information storage means is "0". Therefore, when the information in the information storage unit is not rewritten after the supply of the operating power is stopped, the total value calculated when the supply of the operating power is started is “0”. That is, by determining whether or not the total value calculated when the supply of the operating power is started is “0”, the information in the information storage unit is rewritten after the supply of the operating power is stopped. It is possible to specify whether or not it has not been done.

Features αw4. The control means performs a profit giving process executing means (main side) that executes a profit giving process in a mode corresponding to a set value set as a use target from among a plurality of stages of set values corresponding to the advantage of the player. A function of executing the processing of steps S503 and S504 in the CPU 63),
The configuration is such that predetermined setting-related processing (setting processing and setting corresponding processing) relating to the set value can be executed when supply of operating power is started,
Any one of the characteristics αw1 to αw3 characterized in that the second erasing means erases the information stored in the predetermined storage area at a timing before the timing at which the predetermined setting-related processing is executed. Gaming machine described in.

According to the characteristic αw4, the information stored in the predetermined storage area is erased at a timing before the timing at which the setting-related processing is executed, so that the operating power is not supplied while the setting-related processing is being executed. Even if it is stopped, it is possible to prevent information from being stored in the predetermined storage area at that time.

Feature αw5. The control means executes an abnormality process based on the fact that it is specified that an information abnormality has occurred in the information storage means when the supply of the operating power is started (mainly in the 97th embodiment). The function of executing the processing of step SN812 of the side CPU 63),
The second erasing means erases the information stored in the predetermined storage area at a timing before the timing at which the abnormality processing is executed, according to any one of characteristics αw1 to αw4. Amusement machine.

According to the characteristic αw5, since the information stored in the predetermined storage area is erased at the timing before the timing at which the abnormal processing is executed, the supply of operating power is stopped during the abnormal processing. Even in this case, it is possible to prevent information from being stored in the predetermined storage area at that time.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features αw1 to αw5. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the above characteristic αw group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, in a pachinko machine, the game machine front face section is provided with a dish storage section for storing the game balls given to the player, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as exemplified above, it is necessary to make the state of the information storage means for temporarily storing information suitable, and there is still room for improvement in this respect.

<Characteristic αx group>
Feature αx1. A progress control means (main CPU 63) for controlling the progress of the game,
Notification control means (audio light emission control device 81) for performing notification based on the instruction information transmitted from the progress control means,
Equipped with
The progress control means,
Profit giving process executing means for executing a profit giving process in a mode corresponding to a set value set as a usage target from a plurality of stages of set values corresponding to a player's advantage (step S503 in the main CPU 63 and A function of executing the process of step S504),
Setting-related execution means (97th embodiment) that executes predetermined setting-related processing (step SN807 to step SN810, step SN818 to step SN819 and step SP406) relating to the set value based on the start of supply of operating power. Function of executing the processes of steps SN807 to SN810, step SN818 to step SN819, and step SP406 of the main CPU 63 in FIG.
First transmitting means for transmitting a first type of instruction information (power-on command, power-return command) when the setting-related processing is executed (processing of steps SP503 and SP506 of the main CPU 63 in the 97th embodiment) Function to execute)
Second transmission means (step SP502 and step SP505 of the main CPU 63 in the 97th embodiment) for transmitting the second type of instruction information (setting change command, setting confirmation command) when the setting-related processing is executed Function that executes the process of
Equipped with
The notification control means,
Reception specifying means for specifying whether or not the first type of instruction information is received within a predetermined period (management period after startup) after the supply of operating power is started (sound emission control device in the 97th embodiment) 81, the function of executing the processing of step SP801 to step SP803 and step SP809 to step SP810),
Non-reception-correspondence notification execution means for executing non-reception-correspondence notification (communication abnormality notification) when the first type instruction information is not received within the predetermined period (voice emission in the 97th embodiment) A function of executing the processing of step SP811 of the control device 81),
Second reception-corresponding notification execution means for executing notification corresponding to the reception of the second type instruction information (step SP813 and step SP815 of the sound emission control device 81 in the 97th embodiment) Function that executes the process of
A gaming machine characterized by being equipped with.

According to the characteristic αx1, since the predetermined setting-related process regarding the set value is executed based on the start of the supply of the operating power, the operating power is required to be executed. Need to be temporarily stopped and then the supply of operating power must be started. Therefore, it is possible to make it difficult to execute the predetermined setting-related processing illegally.

When the predetermined setting-related processing is executed in the above configuration, the first type instruction information and the second type instruction information are transmitted from the progress control means to the notification control means. In the case where the notification control means determines whether the first type of instruction information has not been received within a predetermined period after the supply of the operating power has been started, and the first type of instruction information has not been received within the predetermined period. Is notified of non-reception. Accordingly, when an abnormality occurs in the signal path between the progress control unit and the notification control unit, it becomes possible to execute the notification corresponding to the abnormality. Further, the notification control means executes the notification corresponding to the reception of the second type instruction information. As a result, when the progress control means executes a predetermined setting-related process, it is possible to notify the fact. In addition, when the predetermined setting-related processing is executed, both the first type instruction information and the second type instruction information are transmitted, so that the progress control means and the notification control means are connected to each other. The instruction information for specifying whether or not an abnormality has occurred in the signal path and the instruction information for notifying that the predetermined setting-related processing will be executed are individually transmitted. It becomes possible to do.

Feature αx2. The notification control means is configured to execute notification corresponding to the first type of instruction information based on the reception of the first type of instruction information (first light emission control device 81 in the 97th embodiment). Gaming machine according to feature αx1, which is provided with a function of executing the processing of step SP807, step SP808, step SP819, and step SP820.

According to the characteristic αx2, since the notification control means executes the notification corresponding to the reception of the first type instruction information, it is possible to carefully perform the notification of the situation at the start of the supply of the operating power. Becomes

Feature αx3. When the first reception-corresponding notification execution unit receives both the first type instruction information and the second type instruction information, the first reception correspondence notification execution unit outputs the first type instruction information after the predetermined setting-related processing is completed. The gaming machine described in the feature αx2, wherein the corresponding notification is executed.

According to the feature αx3, when the notification control unit receives both the first type instruction information and the second type instruction information, the notification control unit performs the notification after the notification corresponding to the execution of the predetermined setting-related process. The notification corresponding to one type of instruction information is executed. As a result, when the predetermined setting-related processing is being executed, the notification corresponding to it is preferentially executed, while the notification corresponding to the first type instruction information is also executed individually. It becomes possible.

Feature αx4. The first transmitting unit may transmit the first type instruction information even when the supply of operating power is started and the predetermined setting-related process is not executed. The gaming machine according to any one of features αx1 to αx3.

According to the characteristic αx4, the first type instruction information is transmitted from the progress control unit to the notification control unit even when the supply of the operating power is started and the predetermined setting-related process is not executed. It As a result, when the supply of the operating power is started, the progress control unit and the notification control are performed using the first type of instruction information regardless of the content of the process executed as the process when the supply of the operating power is started. It is possible to specify whether or not an abnormality has occurred in the signal path with the means.

Feature αx5. The first transmitting means,
When the supply start first process (step SN815) different from the predetermined setting-related process is executed when the supply of the operating power is started, the first process correspondence information ( A first processing-corresponding transmission means (a function for executing the processing of step SP704 of the main CPU 63 in the 97th embodiment) for transmitting a power-on command);
When the second process at the start of supply (the process of making an affirmative determination in step SN817) different from the predetermined setting-related process when the supply of the operating power is started is executed, the instruction information of the first type Second processing correspondence transmitting means (function of executing the processing of step SP705 of the main CPU 63 in the 97th embodiment) for transmitting the second processing correspondence information (power supply return command) as
The gaming machine according to any one of the features αx1 to αx4.

According to the characteristic αx5, the instruction information of the type corresponding to the content of the processing executed when the supply of the operating power is started is transmitted as the instruction information of the first type. As a result, the supply of operating power is started using the first type of instruction information for specifying whether or not an abnormality has occurred in the signal path between the progress control means and the notification control means. In this case, the notification control means can be made to recognize the content of the processing executed.

Feature αx6. The predetermined setting-related processing includes a first setting-related processing (processing for changing a setting value) and a second setting-related processing (processing for confirming the setting value),
The first processing correspondence transmitting unit transmits the first processing correspondence information as the first type instruction information when the first setting related processing is executed when the supply of the operating power is started,
The second processing correspondence transmitting means may transmit the second processing correspondence information as the first type instruction information when the second setting related processing is executed when the supply of the operating power is started. The gaming machine described in Characteristic αx5.

According to the characteristic αx6, the instruction information of the type corresponding to the content of the process executed when the supply of the operating power is started when the predetermined setting-related process is not executed is transmitted as the first type instruction information. In the configuration, the first process correspondence information of the first type of instruction information is transmitted even when the first setting related process is executed as the predetermined setting related process, and the second of the first type of instruction information is transmitted. The process correspondence information is also transmitted when the second setting related process is executed as the predetermined setting related process. As a result, the instruction information of the type corresponding to the content of the process executed when the supply of the operating power is started when the predetermined setting-related process is not executed is transmitted as the first type instruction information. By using the configuration, it is possible to transmit the first type instruction information corresponding to the content of the process executed as the predetermined setting-related process.

Feature αx7. In the first process at the start of supply and the first setting-related process, a process (step SN807, step SN815, and step SP517) for achieving a predetermined state is executed,
The gaming machine according to feature αx6, wherein the process for setting the predetermined state is not executed in the second process and the second setting-related process at the start of supply.

According to the characteristic αx7, when the process for setting the predetermined state is executed when the supply of the operating power is started, regardless of whether or not the predetermined setting-related process is executed, The first processing correspondence information is transmitted as the instruction information, and whether or not a predetermined setting-related process is executed when the process for setting the predetermined state is not executed when the supply of the operating power is started. Instead, the second processing correspondence information is transmitted as the first type instruction information. Thereby, it becomes possible to make the notification control unit recognize whether or not the process for making the predetermined state is executed by using the first type instruction information.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features αx1 to αx7. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αy group>
Feature αy1. Profit giving process executing means for executing a profit giving process in a mode corresponding to a set value set as a usage target from a plurality of stages of set values corresponding to a player's advantage (step S503 in the main CPU 63 and A function of executing the process of step S504),
Means for executing interrupt processing (first timer interrupt processing) that is periodically activated (function for executing first timer interrupt processing of the main CPU 63 in the 97th embodiment);
Equipped with
The interrupt processing includes processing for advancing the game (steps SP409 to SP421) and setting related processing (steps SP603 to SP610) for executing processing relating to the set values. Characteristic gaming machine.

According to the feature αy1, not only the process for advancing the game in the interrupt process that is regularly activated, but also the setting-related process for executing the process related to the set value is executed. As a result, it becomes possible to regularly execute the process related to the set value in accordance with a predetermined cycle.

Feature αy2. Means for limiting execution of processing for advancing the game in the interrupt processing when the setting-related processing is executed (function of executing processing of step SP408 of the main CPU 63 in the 97th embodiment) The gaming machine described in the feature αy1.

According to the feature αy2, in the situation where the setting related process is executed in the interrupt process, execution of the process for advancing the game in the interrupt process is restricted. This makes it possible to prevent the processing load of one interrupt processing from increasing.

Feature αy3. A function for executing supply start processing (step SN801 to step SN821) for executing supply start processing (step SN801 to step SN821) when the supply of operating power is started (main CPU 63 in the 97th embodiment, step SN801 to step SN821). ),
The gaming machine according to the feature αy1 or αy2, which is in a state where the setting related process is executed based on the setting corresponding start process (step SP501 to step SP511) being executed in the supply start corresponding process. ..

According to the characteristic αy3, the setting related process is executed based on the setting correspondence start process being executed in the supply start correspondence process executed when the supply of the operating power is started. As a result, in order to execute the setting-related processing, it is necessary to temporarily stop the supply of the operating power and then start the supply of the operating power. It is possible to make it difficult to perform.

Features αy4. A means for executing post-end processing (step SN822) after the supply start handling processing is completed (function of executing residual processing of the main CPU 63 in the 97th embodiment),
The setting related process is not executed based on the setting corresponding end process (the process of making an affirmative determination in step SP513) being executed in the supply start corresponding process.
The gaming machine according to feature αy3, wherein when the setting correspondence start processing is executed in the supply start correspondence processing, the supply start correspondence processing does not end until the setting correspondence end processing is executed.

According to the feature αy4, when the setting correspondence start processing is executed in the supply start correspondence processing, the supply start correspondence processing is not ended until the setting correspondence end processing is executed. The post-termination process is not executed until the supply start handling process is terminated. This makes it possible to prevent the post-end processing from being executed in a situation where the setting-related processing can be executed.

Feature αy5. The interrupt processing includes predetermined monitoring processing (step SP602) for monitoring whether or not a predetermined monitoring target has occurred,
The gaming machine according to any one of features αy1 to αy4, wherein the predetermined monitoring process is executed even in a situation where the setting-related process is executed in the interrupt process.

According to the feature αy5, the predetermined monitoring process is executed by the interrupt process even in the situation where the setting related process is executed by the interrupt process. As a result, it is possible to monitor whether or not the predetermined monitoring target is generated even in the situation where the process related to the set value is being executed.

Feature αy6. The game machine according to any one of features αy1 to αy5, wherein a process for changing the setting value is executed as the setting-related process.

According to the feature αy6, it is possible to regularly execute the process for changing the set value in accordance with a predetermined cycle.

For the configurations of the features αy1 to αy6, the features A1 to A15, the features B1 to B7, the features C1 to C5, the features D1 to D10, the features E1 to E6, the features F1 to F3, the features G1 to G18, and the features H1 to H1. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic αz group>
Features αz1. Profit giving process executing means for executing a profit giving process in a mode corresponding to a set value set as a usage target from a plurality of stages of set values corresponding to a player's advantage (step S503 in the main CPU 63 and A function of executing the process of step S504),
Setting-related executing means for executing setting-related processing (step SP603 to step SP610) for executing the processing relating to the set value (function of executing processing of step SP603 to step SP610 of the main CPU 63 in the 97th embodiment) When,
In a situation where the setting related process is executed, a predetermined monitoring execution unit (step SP602) for executing a predetermined monitoring process (step SP602) for monitoring whether or not a predetermined monitoring target has occurred (main CPU 63 in the 97th embodiment). Function for executing the processing of step SP602 of)),
A gaming machine characterized by being equipped with.

According to the characteristic αz1, the predetermined monitoring process for monitoring whether or not the predetermined monitoring target has occurred is executed even in the situation where the setting related process for executing the process related to the setting value is executed. As a result, it is possible to monitor whether or not the predetermined monitoring target has occurred, even when the setting-related processing is executed, and it is possible to deal with it when the predetermined monitoring target has occurred. Become.

Features αz2. In the situation where the setting-related processing is executed, a means for restricting the execution of the processing for advancing the game (function for executing the processing of step SP408 of the main CPU 63 in the 97th embodiment) is provided. The gaming machine according to the characteristic feature αz1.

According to the feature αz2, in the situation where the setting related process is executed, execution of the process for advancing the game in the interrupt process is restricted. As a result, it is possible to prevent the game from progressing in the situation where the process related to the set value is being executed. In this case, by providing the configuration of the above characteristic αz1, it is possible to monitor whether or not the predetermined monitoring target is generated even in the situation where the execution of the process for advancing the game is restricted. It will be possible.

Features αz3. A function for executing supply start processing (step SN801 to step SN821) for executing supply start processing (step SN801 to step SN821) when the supply of operating power is started (main CPU 63 in the 97th embodiment, step SN801 to step SN821). ),
The gaming machine according to the feature αz1 or αz2, which is in a state where the setting related process is executed based on the setting corresponding start process (step SP501 to step SP511) being executed in the supply start corresponding process. ..

According to the characteristic αz3, the setting related process is executed based on the setting start process executed in the supply start process executed when the supply of the operating power is started. The setting related process is executed based on the start of the supply. As a result, in order to execute the setting-related processing, it is necessary to temporarily stop the supply of the operating power and then start the supply of the operating power. It is possible to make it difficult to perform. In this case, by providing the configuration of the characteristic αz1, whether or not the predetermined monitoring target is generated even in the situation where the supply start handling process based on the start of the supply of the operating power is being executed. It becomes possible to monitor that.

Features αz4. A means for executing post-end processing (step SN822) after the supply start handling processing is completed (function of executing residual processing of the main CPU 63 in the 97th embodiment),
The setting related process is not executed based on the setting corresponding end process (the process of making an affirmative determination in step SP513) being executed in the supply start corresponding process.
The gaming machine according to feature αz3, wherein, when the setting correspondence start processing is executed in the supply start correspondence processing, the supply start correspondence processing does not end until the setting correspondence end processing is executed.

According to the characteristic αz4, when the setting correspondence start processing is executed in the supply start correspondence processing, the supply start correspondence processing is not ended until the setting correspondence end processing is executed. The post-termination process is not executed until the supply start handling process is terminated. This makes it possible to prevent the post-end processing from being executed in a situation where the setting-related processing can be executed. In this case, since the configuration of the characteristic αz1 is provided, it is possible to monitor whether or not the predetermined monitoring target is generated even in the situation where the post-termination process is not executed.

Features αz5. A means for executing an interrupt process (first timer interrupt process) which is activated periodically (a function for executing the first timer interrupt process of the main CPU 63 in the 97th embodiment),
The gaming machine according to any one of features αz1 to αz4, wherein the predetermined monitoring process is executed in the interrupt process.

According to the feature αz5, the predetermined monitoring process is executed in the interrupt process that is regularly activated. As a result, it becomes possible to regularly monitor whether or not a predetermined monitoring target has occurred in accordance with a predetermined cycle.

Features αz6. The game machine according to any one of features αz1 to αz5, wherein a process for changing the setting value is executed as the setting-related process.

According to the feature αz6, a process for changing the setting value is executed as the setting-related process. Although it takes a certain amount of time to perform the setting value changing work, even if the setting value changing work is being performed due to the configuration of the characteristic αz1, the predetermined monitoring target It is possible to monitor whether or not it has occurred.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features αz1 to αz6. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the above-mentioned characteristic αx group, the above-mentioned characteristic αy group, and the above-mentioned characteristic αz group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, in a pachinko machine, the game machine front face section is provided with a dish storage section for storing the game balls given to the player, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, it is necessary to suitably execute the processing relating to the set value that determines the degree of advantage of the player, and there is still room for improvement in this respect.

<Characteristic βA group>
Feature βA1. Output starting means for starting external output of a predetermined external signal (security signal) on the basis of occurrence of a predetermined output trigger (function of executing the process of step SP902 of the main CPU 63 in the 97th embodiment);
Period measuring means (a function for executing the process of step SP901 of the main CPU 63 in the 97th embodiment) for measuring the output continuation period based on the occurrence of the predetermined output trigger;
When the measurement of the output continuation period is completed in the situation where the predetermined external signal is being externally output, the output ending means (the main CPU 63 in the 97th embodiment, which ends the external output of the predetermined external signal). Function for executing the processing of step SP914 of)),
Equipped with
When the predetermined output trigger occurs in a situation where the predetermined external signal is being externally output, the period measuring unit extends the output continuation period measured at that time (the 97th extension unit). A function of executing the processing of step SP901 of the main CPU 63 in the above embodiment).

According to the characteristic βA1, since the predetermined external signal is output to the outside based on the occurrence of the predetermined output trigger, it is possible to make the gaming hall management computer recognize that the predetermined output trigger has occurred. Further, since the external output of the predetermined external signal is continued for the output continuation period, it becomes easy to recognize that the predetermined external signal is externally output in the management computer of the game hall.

In this case, when a predetermined output trigger newly occurs in a situation where the predetermined external signal is externally output, the output continuation period measured at that time is extended. This makes it possible to integrate the external outputs of the predetermined external signals for the plurality of output triggers into one output when the predetermined output triggers repeatedly occur in a short period. Therefore, the frequency with which the external output of the predetermined external signal is started can be prevented from becoming excessively high.

Feature βA2. The feature βA1 is characterized in that the extension means newly starts measurement of the output duration period when the predetermined output trigger occurs in a situation where the predetermined external signal is externally output. Game machine.

According to the characteristic βA2, when the predetermined output trigger occurs in the situation where the predetermined external signal is being output externally, it is only necessary to newly start the measurement of the output continuation period. It is possible to simplify the processing configuration for performing external output.

Feature βA3. Profit giving process executing means for executing a profit giving process in a mode corresponding to a set value set as a usage target from a plurality of stages of set values corresponding to a player's advantage (step S503 in the main CPU 63 and A function of executing the process of step S504),
Setting-related executing means for executing setting-related processing (step SP603 to step SP610) for executing the processing relating to the set value (function of executing processing of step SP603 to step SP610 of the main CPU 63 in the 97th embodiment) When,
Equipped with
The predetermined output trigger occurs when the setting related processing is started,
The gaming machine according to feature βA1 or βA2, wherein the predetermined output trigger is generated when the setting-related process is ended.

According to the characteristic βA3, a predetermined output trigger is generated and a predetermined external signal is externally output when the setting-related process is started and ended, respectively. Therefore, the start timing and the end of the setting-related process are performed. It becomes possible to make the management computer of the game hall recognize the timing. However, it is assumed that the setting-related processing ends in a period shorter than the output continuation period. In this case, if the configuration is such that the predetermined external signal is externally output at each of the start and the end of the setting-related process, the frequency of starting the external output of the predetermined external signal increases. On the other hand, when the predetermined output trigger is repeatedly generated in a short period with the configuration of the characteristic βA1, the external output of the predetermined external signal for the plurality of output triggers is integrated into one output. This makes it possible to prevent the frequency at which the external output of the predetermined external signal is started from becoming excessively high.

Feature βA4. Erasing means for erasing the information stored in the information storage means based on the occurrence of the erasure trigger when the supply of the operating power is started (step SN807 of the main CPU 63 in the 97th embodiment, step SN807). SN815 and the function of executing the processing of step SP517),
The gaming machine according to any one of features βA1 to βA3, wherein the predetermined output trigger occurs when the erasing is performed by the erasing means.

According to the characteristic βA4, when the information stored in the information storage means is erased, a predetermined output trigger occurs and the predetermined external signal is externally output. As a result, it becomes possible to make the management computer of the game hall recognize that the deletion of the information stored in the information storage means has occurred.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features βA1 to βA4. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the above characteristic βA group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, in a pachinko machine, the game machine front face section is provided with a dish storage section for storing the game balls given to the player, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machines such as the above examples, it is necessary to preferably output the signal externally, and there is still room for improvement in this respect.

<Characteristic βB group>
Feature βB1. A control unit (main CPU 63) that executes various processes and temporarily stores information in the information storage unit (main RAM 65) when the processes are executed,
The control means is
Profit giving process executing means for executing a profit giving process in a mode corresponding to a set value set as a usage target from a plurality of stages of set values corresponding to a player's advantage (step S503 in the main CPU 63 and A function of executing the process of step S504),
Setting change processing for changing the setting value to be used (step SN807 to step SN810 and step SP406) based on the setting change operation being performed when the supply of operating power is started. A setting changing means (a function of executing the processing of steps SN807 to SN810 and step SP406 of the main CPU 63 in the 97th embodiment);
When the setting changing process is executed, an erasing unit that erases information in at least a part of the storage area of the information storage unit (the processes of step SN807 and step SP517 of the main CPU 63 in the 97th embodiment are executed. Function),
Abnormality specifying means (a function for executing the abnormality determination processing of the main CPU 63 in the 97th embodiment) for specifying that a predetermined abnormality has occurred when the supply of operating power is started,
Abnormality handling means for setting the abnormality handling state based on the fact that the predetermined abnormality has been identified by the abnormality identifying means (affirmative determination in step SN811 of the main CPU 63 in the 97th embodiment). Function),
Equipped with
When the setting change operation is performed when the supply of operating power is started, the setting change process is executed even if the abnormality specifying unit specifies that the predetermined abnormality has occurred. A gaming machine characterized by that.

According to the characteristic βB1, the setting change process is executed based on the start of the supply of the operation power. Therefore, in order to execute the setting change process, the operation power supply is temporarily stopped. Then, it becomes necessary to start the supply of operating power after that. Therefore, it is possible to make it difficult to execute the predetermined setting changing process illegally. Further, since the information in at least a part of the storage area in the information storage means is erased when the setting change processing is executed, predetermined information is stored in the information storage means when the setting change processing is executed. It becomes possible not to be in a state. Further, when it is specified that the predetermined abnormality has occurred when the supply of the operating power is started, the abnormality response state is set. This makes it possible to prevent the processing for advancing the game from being executed despite the occurrence of the predetermined abnormality.

In the above configuration, when the setting change operation is performed when the supply of the operating power is started, the setting change process is executed even if it is specified that the predetermined abnormality has occurred. This makes it possible to give priority to the execution of the setting change process based on the setting change operation, rather than setting the abnormality correspondence state to the occurrence of the predetermined abnormality. .. Further, when the setting change process is executed, the information in at least a part of the storage area in the information storage unit is erased and the set value to be used is newly set, so that the predetermined abnormality is resolved. It is highly possible that it is in a normal state. Therefore, even if the execution of the setting change process is prioritized rather than the abnormal response state, there is no problem regarding the progress of the game.

Feature βB2. Since the setting changing operation is performed when the supply of the operating power is started, the setting changing process is executed even if the abnormality specifying unit specifies that the predetermined abnormality has occurred. In this case, after the processing for changing the setting ends, the processing for advancing the game without entering the abnormal corresponding state (step SN822 and step SP409 to step SP421) is started, which is a characteristic βB1. The game machine described.

According to the characteristic βB2, when the setting change operation is performed when the supply of the operating power is started, the setting change process is only executed even if it is specified that the predetermined abnormality has occurred. Instead, after the setting change process is finished, a process for advancing the game without starting the abnormal response state is started. This makes it possible to smoothly start the process for advancing the game in the configuration in which the setting change process is prioritized.

Feature βB3. The abnormality identifying means stores abnormality identifying information (information of "1" set in the abnormality flag (fifth bit B5)) in the information storage means when it is identified that the predetermined abnormality has occurred. Is something that
The erasing means does not erase the abnormality specifying information when the setting changing process is started, and erases the abnormality specifying information when the setting changing process is ended. The gaming machine described in βB1 or βB2.

According to the characteristic βB3, the abnormality specifying information is not erased from the information storage unit at the start of the setting change process, and the abnormality specifying information is erased from the information storage unit at the end of the setting change process. As a result, when the operation power supply is stopped in the middle of the setting change process while preventing the abnormal response state after the setting change process is completed, the subsequent operation power supply is started. In addition, it becomes possible to store the abnormality specifying information in the information storage means.

Feature βB4. The control means determines that the setting change operation has not been performed when the supply of the operating power is stopped in the situation where the process for changing the setting is executed, and when the supply of the operating power is subsequently started. Also comprises means for executing the setting change process (function of making an affirmative decision in step SN813 of the main CPU 63 in the 97th embodiment),
In the case where the supply of the operating power is stopped in the situation where the setting changing process is being executed and the setting changing operation is not performed when the supply of the operating power is subsequently started, Any one of the characteristics βB1 to βB3 characterized in that when the abnormality specifying means specifies that the predetermined abnormality has occurred, the setting change processing is not executed and the abnormality corresponding state is established. The game machine described.

According to the characteristic βB4, when the supply of the operating power is stopped in the situation where the process for changing the setting is executed, the setting change operation is not performed when the supply of the operating power is subsequently started. Also, since the setting change process is executed, it is possible to give priority to the restart of the setting change process when the setting change process ends midway. In this case, if the supply of operating power is stopped in the situation where the setting change process is being executed, and if the setting change operation is not performed when the supply of operating power is started after that If it is specified that the predetermined abnormality has occurred, the setting change process is not executed and the abnormality response state is entered. As a result, it is possible to give priority to setting the abnormality response state to the occurrence of the predetermined abnormality when the setting change operation is not performed when the supply of the operating power is started.

Feature βB5. An operation of executing an erasing process (step SN815) for erasing the information in at least a part of the storage area in the information storage means based on the fact that the erasing operation is performed when the supply of the operating power is started. Corresponding erasing means (function of executing the process of step SN815 of the main CPU 63 in the 97th embodiment),
Even when the erasing operation is performed when the supply of the operating power is started, the erasing process is executed when the abnormality identifying unit identifies that the predetermined abnormality has occurred. The gaming machine according to any one of the features βB1 to βB4, wherein the gaming machine is brought into the abnormal response state without any.

According to the characteristic βB5, if the erase operation is performed when the supply of the operating power is started, the information in at least a part of the storage area in the information storage unit is erased. This makes it possible to erase the information stored in the information storage means as needed. In this case, even if the erasing operation is performed when the supply of the operating power is started, if it is determined that the predetermined abnormality is occurring, the erasing process is not performed and the abnormality is not performed. It becomes a correspondence state. This makes it possible to give priority to setting an abnormality-corresponding state in response to occurrence of a predetermined abnormality, rather than erasing information stored in the information storage means.

It should be noted that features A1 to A15, features B1 to B7, features C1 to C5, features D1 to D10, features E1 to E6, features F1 to F3, features G1 to G18, and features H1 to the configurations of the features βB1 to βB5. H7, features I1-I9, features J1-J4, features K1-K7, features L1-L20, features M1-M7, features N1-N6, features O1-O11, features P1-P12, features Q1-Q5, features R1-. R17, Features S1 to S8, Features T1 to T13, Features U1 to U8, Features V1 to V6, Features W1 to W11, Features X1 to X11, Features Y1 to Y11, Features Z1 to Z10, Features a1 to a3, Features b1. b7, features c1 to c21, features d1 to d10, features e1 to e9, features f1 to f6, features g1 to g6, features h1 to h13, features i1 to i7, features j1 to j6, features k1 to k16, features 11 to 11. l5, features m1 to m3, features n1 to n10, features o1 to o7, features p1 to p7, features q1 to q8, features r1 to r7, features s1 to s4, features t1 to t5, features u1 to u10, features v1 to v8, features w1 to w8, features x1 to x6, features y1 to y9, features z1 to z6, features αA1 to αA10, features αB1 to αB6, features αC1 to αC13, features αD1 to αD9, features αE1 to αE5, and features αF1 to αF9, features αG1 to αG10, features αH1 to αH11, features αI1 to αI8, features αJ1 to αJ14, features αK1 to αK8, features αL1 to αL11, features αM1 to αM8, features αN1 to αN6, features αO1 to αO7, features αP1. αP7, features αQ1 to αQ9, features αR1 to αR8, features αS1 to αS3, features αT1 to αT4, features αU1 to αU10, features αV1 to αV5, features αW1 to αW9, features αX1 to αX4, features αY1 to αY11, features αZ1 to αZ4, features αa1 to αa3, features αb1 to αb9, features αc1 to αc7, features αd1 to αd9, features αe1 to αe13, features αf1 to αf13, features αg1 to αg8, features αh1 to αh11, features αi1 to αi15, features αj1. αj12, features αk1 to αk11, features αl1 to αl18, features αm1 to αm11, features αn1 to αn9, features αo1 to αo6, features αp1 to αp3, features αq1 to αq9, features αr1 to αr9, features αs1 to αs8, features αt1. αt8, features αu1 to αu8, features αv1 to αv10, features αw1 to αw5, features αx1 to αx7, features αy1 to αy6, features αz1 to αz6, features βA1 to βA4. Alternatively, any one or more of the features βB1 to βB5 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the characteristic βB group, the following problems can be solved.

Pachinko machines and slot machines are known as game machines. For example, in a pachinko machine, the game machine front face section is provided with a dish storage section for storing the game balls given to the player, and the game balls stored in the dish storage section are guided to the game ball launching device, It is fired toward the game area according to the firing operation of the player. Then, for example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage unit, for example. In addition, in the pachinko machine, a configuration including an upper plate storage part and a lower plate storage part as a plate storage part is also known, and in this case, the game balls stored in the upper plate storage part are game ball launching devices. The game balls that have been surplus in the upper dish storage section are discharged to the lower dish storage section.

In the slot machine, the lottery process is executed by the control means when the start lever is operated and a new game is started while the medals are bet. When the lottery process is executed, the rotation start control is executed by the control means to start the rotation of the reel, and when the stop button is operated during the rotation of the reel, the control means is executed. The rotation of the reel is stopped by executing the rotation stop control. Then, when the stop result after the rotation of the reels is stopped corresponds to the winning combination of the lottery process, the privilege corresponding to the winning combination is given to the player.

Here, in the gaming machine as illustrated above, the process at the time of starting the supply of the operating power needs to be suitably executed, and there is still room for improvement in this respect.

The following is a basic configuration of a gaming machine to which each of the above features can be applied or applied to each feature.

Pachinko machine: operating means operated by a player, game ball launching means for launching a game ball based on the operation of the operating means, a ball passage for guiding the launched game ball to a predetermined game area, and a game area A gaming machine that is provided with each game component arranged therein, and gives a bonus to a player when a game ball passes through a predetermined passage portion of the respective game components.

Rotating type gaming machine such as slot machine: equipped with a pattern display device for variably displaying a plurality of patterns, the variable display of the plurality of patterns is started due to the operation of the starting operation means, and due to the operation of the stop operation means In addition, or after a lapse of a predetermined time, the variable display of the plurality of patterns is stopped, and a gaming machine which gives a privilege to the player according to the stopped patterns.

10... Pachinko machine, 12... Game machine main body, 14... Front door frame, 24a... Out opening, 28... Launching operation device, 31... General winning opening, 32... Special electric winning device, 33... First operating opening, 34... No. 2 working port, 35... through gate, 37a... special figure display section, 37b... special figure reservation display section, 38a... public figure display section, 38b... general figure reservation display section, 42a... first winning hole detection sensor, 43a... Second winning opening detection sensor, 44a... Third winning opening detection sensor, 45a... Special electric power detection sensor, 46a... First working opening detection sensor, 47a... Second working opening detection sensor, 48a... Out opening detection sensor, 49a... Gate Detection sensor, 62... MPU, 63... Main CPU, 64... Main ROM, 65... Main RAM, 68a... Setting key insertion part, 68b... Update button, 68c... Reset button, 69a... First notification display device , 69b... Second notification display device, 69c... Third notification display device, 78... Power supply/launch control device, 81... Audio emission control device, 112... Management CPU 117... History memory, 171... Separate storage Memory, 181-186... History memory for settings 1-6, 191... First history memory, 192... Second history memory, 201... First notification display device, 201a-201g... Display segment, 202... 2nd notification display device, 202a-202g... display segment, 203... 3rd notification display device, 204... 4th notification display device, 221... specific control work area, 222... specific control display area Stack area, 223... Work area for non-specific control, 224... Stack area for non-specific control, 231,... Normal counter area, 232... Open/close execution mode counter area, 233... High frequency support mode counter area, 234 ... Calculation result storage area, 241... Management RAM, 251,... Reset signal output section, 252... Program monitoring section, 266... Display IC, 271... First display data buffer, 273... Third display data buffer, 311... Present area 312... 1st history area, 313... 2nd history area, 314... 3rd history area, 321-324... Display segment, 325... Setting correspondence storage area, 325a-325f... 1st-6th setting information storage area 326... Setting correspondence storage area, 326a to 326c... First to third setting information storage area, 341... Setting reference area, 342... Setting update area, 352... Sound light side MPU, 353... Sound light side CPU, 355... Sound side RAM, 356... RTC, 357... RTC memory Memory, 361... OFF confirmation flag, 371... Area to be cleared, 391... First display allocation table for special drawing, 392... Second display allocation table for special drawing, 393... First display allocation for general drawing Minute table, 394... Second display sorting table for general map, 416... Special electric prize winning device, 423a... General figure display section, 425... First special figure display section, 426... Second special figure display section, 429... Special Display unit, 481... 15R display unit, 483... 6R display unit, 484... Small hit display unit, 512... Movable body, 515... Address counter, 515a... Upper byte, 515b... Lower byte, 516... Carry flag, 541... Normal Set value suggestion lottery table group at suggestion, 542... Set value suggestion lottery table group at suggestion limit, 551... Radio wave detection sensor, 552... Magnetic detection sensor, 553... Vibration detection sensor, 554a... Timer counter for starting demo, 555b ... Waiting state flag, 556... Transmission random number storage counter, 566... Threshold table, 573... Threshold table, 596... Entrance count counter area, 601... First management buffer, 601a-601d... 0th-3rd storage area, 602 ... 2nd management buffer, 602a-602j... 0th-9th storage area, 603... 1st write pointer, 604... 2nd write pointer, 606a... 1st unit update area, 606b... Area immediately before the 1st calculation period, 606c...

Claims (7)

A progress control means for controlling the progress of the game,
A notification control means for performing notification based on the instruction information transmitted from the progress control means,
Equipped with
The progress control means,
A profit giving process executing means for executing a profit giving process in a mode corresponding to a setting value set as a usage target from a plurality of setting values corresponding to a player's advantage,
Setting-related executing means for executing a predetermined setting-related process relating to the set value based on the start of supply of operating power,
First transmitting means for transmitting a first type of instruction information when the setting related processing is executed;
Second transmitting means for transmitting second type instruction information when the setting-related processing is executed;
Equipped with
The notification control means,
Reception specifying means for specifying whether or not the first type of instruction information has been received within a predetermined period from the start of supply of operating power,
A non-reception-corresponding notification execution means for executing non-reception-corresponding notification when the first type instruction information is not received within the predetermined period;
Second reception-corresponding notification executing means for executing notification corresponding to the second type of instruction information received,
A gaming machine characterized by being equipped with. 2. The notification control means comprises first reception-corresponding notification execution means for executing notification corresponding to the first type instruction information received. Gaming machine described in. When the first reception-corresponding notification execution means receives both the first-type instruction information and the second-type instruction information, the first-reception-correspondence notification execution unit changes the first-type instruction information to the first-type instruction information after the predetermined setting-related processing is completed. The gaming machine according to claim 2, wherein a corresponding notification is executed. The first transmitting means may transmit the first type instruction information even when the supply of operating power is started and the predetermined setting-related processing is not executed. The gaming machine according to any one of claims 1 to 3. The first transmitting means,
A first process correspondence information is transmitted as the first type instruction information when a first process at the start of supply different from the predetermined setting-related process is executed when the supply of the operating power is started. Processing correspondence transmission means,
A second process correspondence information is transmitted as the first type instruction information when a second process at the start of supply different from the predetermined setting related process is executed when the supply of the operating power is started. Processing correspondence transmission means,
The gaming machine according to any one of claims 1 to 4, further comprising: There is a first setting related process and a second setting related process as the predetermined setting related process,
The first processing correspondence transmitting unit transmits the first processing correspondence information as the first type instruction information when the first setting related processing is executed when the supply of the operating power is started,
The second processing correspondence transmitting means may transmit the second processing correspondence information as the first type instruction information when the second setting related processing is executed when the supply of the operating power is started. The gaming machine according to claim 5, which is characterized in that. In the first process at the start of supply and the first setting-related process, a process for setting a predetermined state is executed,
7. The gaming machine according to claim 6, wherein the processing for setting the predetermined state is not executed in the second processing and the second setting-related processing when the supply is started.

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